KR100787427B1 - Built-in plasma display apparatus - Google Patents

Abstract

An object of the present invention is to provide a plasma display device having a structure that can be built in a residential space or an office space without the need for a bracket or a boss for hanging it on a wall. And a substrate, which is spaced apart in front of or behind the glass window and forms a discharge space between the glass window, a plurality of electrodes disposed between the substrate and the glass window and generating plasma discharge therebetween; Provided is a plasma display device including a phosphor layer disposed in a space and emitting visible light to the outside through a substrate or a glass window in accordance with a plasma discharge, a discharge gas disposed in the discharge space, and a circuit portion for applying a voltage to the electrodes. .

Description

Built-in plasma display apparatus

1 is an exploded perspective view showing a conventional plasma display device.

2 is a perspective view showing a living space provided with a built-in plasma display device according to a first embodiment of the present invention.

3 is an exploded perspective view showing an example of a built-in plasma display device according to a first embodiment of the present invention.

4 is an exploded perspective view illustrating an enlarged portion A of FIG. 3.

5 is a cross-sectional view taken along the line VV of FIG. 4.

FIG. 6 is a diagram illustrating an arrangement state of the circuit part and the electrodes illustrated in FIG. 3.

FIG. 7 is a timing diagram for describing a first embodiment of a drive signal of the panel shown in FIG. 2.

8 is an exploded perspective view illustrating a modification of FIG. 3.

9 is an exploded perspective view illustrating part B of FIG. 8 in an enlarged manner.

10 is an exploded perspective view illustrating a built-in plasma display device according to still another embodiment of the present invention.

FIG. 11 is an exploded perspective view illustrating an enlarged portion C of FIG. 10.

<Brief description of the major symbols in the drawings>

100, 200, 300: built-in display device

101: living space 110: glass

115: frame 120: front substrate

121, 221, and 321: sustain discharge electrodes 122, 222, and 322: scan electrodes

123, 223, 323: sustain electrode 130: back substrate

131, 231, and 331: address electrodes 137, 237 and 337: partition walls

138, 238, 338: phosphor layers 150, 250, 350: circuit portion

152, 252, 352: holding circuit portion 153, 253, 353: address circuit portion

190, 390: substrate 310: mirror

315: mirror frame

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display device, and more particularly, to a built-in plasma display device having a structure that is built in to a living space or an office space and has a structure for representing an image to the outside using plasma discharge.

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.

Figure 1 shows a conventional conventional plasma display device. Referring to FIG. 1, a conventional plasma display apparatus 10 includes a plasma display panel 20, a chassis base 40 supporting the plasma display panel 20, the plasma display panel 20 and a chassis base. (40) The circuit part 50 provided in the back side is basically provided.

The plasma display panel 20 includes a front substrate and a back substrate, and electrodes are formed between the panels to implement an image. It is preferable that a filter 25 is provided on the front surface of the plasma display panel 20. The filter 25 has an electromagnetic shielding layer for blocking electromagnetic waves harmful to a human body generated when the plasma display panel 20 is driven. This includes.

In addition, a chassis base 40 is disposed behind the plasma display panel 20 configured as described above, and the chassis base 40 supports the plasma display panel 20, and from the plasma display panel 20. It receives heat and releases it to the outside.

The plasma display panel 20 is fixed to the chassis base 40 by an adhesive member 35 such as a double-sided tape. In addition, a heat dissipation sheet 30, which is a heat conduction medium, is provided between the plasma display panel 20 and the chassis base 40, and the heat dissipation sheet 30 receives heat generated from the plasma display panel 20 from the chassis base. It functions to discharge to the outside via (40).

The circuit unit 50 is mounted to the rear of the chassis base 40 coupled to the plasma display panel 20. The circuit unit 50 includes elements for driving the plasma display panel 20.

The display panel 20 and the chassis base 40 configured as described above are accommodated by the case 70. The case 70 includes a front cabinet 71 installed in front of the display panel 20 and the chassis. It may be made of a back cover 72 installed at the rear of the base 40.

On the other hand, the circuit board 50 drives the plasma display panel 20 by transmitting an electrical signal to the plasma display panel 20 by at least one signal transmission means 80.

However, the plasma display apparatus 10 having such a structure requires a chassis base 40 formed of iron or aluminum in order to support the plasma display panel 20. As a result, the total weight of the plasma display apparatus 10 becomes large, and there is a problem that a bracket or the like as well as a wall boss are additionally inserted to hang the plasma display apparatus 10 on the wall.

In addition, since the chassis base 40 is manufactured through a press mold or a casting mold, a manufacturing cost for manufacturing such a press mold or a casting mold and a material cost of the chassis base 40 itself increase. In addition, an adhesive member 35 is required to bond the chassis base 40 and the plasma display panel 20 to increase the material cost of the adhesive member and increase the manufacturing process.

In addition, since the plasma display panel 20 is adhered to the chassis base 40 by the adhesive member 35, the rear surface of the plasma display panel 20 is not directly exposed to the outside air so that the plasma display panel 20 is generated from the plasma display panel 20. It is not easy to dissipate heat to the outside. In order to solve this problem, although the heat dissipation sheet 30 is interposed between the plasma display panel 20 and the chassis base 40, there is also a problem that the heat dissipation sheet material cost and manufacturing process increases.

An object of the present invention is to provide a plasma display apparatus having a structure in which a chassis base is unnecessary.

Another object of the present invention is to provide a plasma display device having a structure that can be built in a residential space or an office space without a bracket or a boss for hanging the plasma display device on a wall.

Still another object of the present invention is to provide a plasma display apparatus having a structure capable of effectively radiating heat generated from the rear surface of a plasma display panel to the outside without using a separate member.

A built-in plasma display device according to a first embodiment of the present invention for achieving the above object, the substrate is disposed in front of or behind the glass window to form a discharge space between the glass window, and A plurality of electrodes disposed between the substrate and the glass window and generating plasma discharge therebetween, and a phosphor layer disposed in the discharge space and emitting visible light to the outside through the substrate or the glass window according to the plasma discharge. And a discharge gas disposed in the discharge space, and a circuit unit for applying a voltage to the electrodes.

In this case, the glass window is preferably a conventional glass window disposed in a living space such as a living space or an office space.

In this case, the electrodes preferably include sustain discharge electrodes for generating sustain discharge and address discharge together with the address electrodes in a discharge space disposed between the address electrodes and the address electrodes.

The circuit part may include a sustain circuit part for applying a voltage to the sustain discharge electrode and an address circuit part for applying a voltage to the address electrodes, wherein at least a portion of the sustain circuit part and / or the address circuit part is an edge of the glass window. It is preferable to be supported by the frame disposed along.

Here, the address electrodes are formed in contact with or adjacent to the front of the glass window. The sustain discharge electrodes may be formed in contact with or adjacent to a rear surface of the substrate, and the address electrodes and the sustain discharge electrodes may be filled by a dielectric layer, respectively, and an image may be emitted to the outside through the substrate.

In contrast, the address electrodes are formed in contact with or adjacent to the front surface of the substrate, the sustain discharge electrodes are formed in contact with or adjacent to the rear surface of the glass window, and the address electrodes and the sustain discharge electrodes are respectively filled by a dielectric layer. The image may be emitted to the outside through the glass window.

Preferably, a voltage is applied to the electrodes in a single scan method.

In addition, a heat conductive member is attached to a surface of the glass window that is not bonded to the substrate, and in this case, the heat conductive member is made of a metal material and is in contact with the circuit part.

A built-in plasma display device according to a second embodiment of the present invention is a front substrate which is disposed in a living space such as a living space or an office space and is spaced apart in front of the glass window to form a discharge space between the glass window. Partitions between the front substrate and the glass window and defining the discharge cells together with the front substrate and the glass window, and a sustain electrode extending side by side in a direction in which the discharge cells extend from the rear of the front substrate; A scan electrode, a front dielectric layer covering the sustain electrode and the scan electrodes, a glass window disposed parallel to the rear of the front substrate, and extending in a direction crossing the direction in which the sustain electrode and the scan electrodes extend from the front of the glass window Addressed electrodes, a back dielectric layer covering the address electrodes, and a plurality of address electrodes And a phosphor layer, and a discharge gas in the discharge cells, an address circuit for applying a voltage to the address electrodes, Y circuit for applying a voltage to the scan electrode.

In this case, a voltage is applied to the sustain electrode, the scan electrode, and the address electrodes such that a series of driving cycles consisting of a reset period, an address period, and a sustain period is repeated, and the voltage applied to the sustain electrode through the driving period is It is desirable to have a constant voltage of constant magnitude.

In addition, the constant voltage applied to the sustain electrode is preferably a ground voltage.

On the other hand, the built-in plasma display device according to a third embodiment of the present invention, the glass window provided in a living space, such as a living space or an office space, and spaced apart behind the glass window to form a discharge space between the glass window Disposed between the rear substrate, the rear substrate and the glass window, barrier ribs defining discharge cells together with the rear substrate and the glass window, and a sustain electrode extending side by side in a direction in which the discharge cells extend from the rear of the glass window. And a front dielectric layer covering the scan electrodes, the sustain electrode and the scan electrodes, address electrodes extending in a direction crossing the direction in which the sustain electrode and the scan electrodes extend from the front of the glass window, and a back surface covering the address electrode. A dielectric layer, a phosphor layer disposed in the discharge cells, and a discharge in the discharge cells And, with the address and a circuit unit for applying a voltage to the address electrodes, Y circuit for applying a voltage to the scan electrode.

On the other hand, the built-in plasma display device according to a fourth embodiment of the present invention is a substrate disposed between the mirror and the front or rear of the mirror to form a discharge space between the mirror, and disposed between the substrate and the mirror And a plurality of electrodes for generating a plasma discharge therebetween, a phosphor layer disposed in the discharge space, and emitting a visible light to the outside through the substrate or mirror according to the plasma discharge, and disposed in the discharge space. And a circuit portion for applying a voltage to the electrodes.

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

2, the plasma display apparatus 100 according to the first exemplary embodiment of the present invention includes a substrate 190 and a glass window 110. In this case, the glass window 110 refers to a product made of glass as installed in the living space 101 such as a living space or an office space, and is, for example, a porch supported by the frame 113 by opening and closing the living room and the veranda. It means a glass window, a bedroom glass window that opens between the bedroom and the outside, and a square fish tank.

However, in the present invention, the glass window is not limited thereto, and the glass window is included in the present invention as long as the glass product can be disposed in an office space or a residential space. In addition, the substrate 190 may be a back substrate 130 (see FIG. 3) disposed behind the glass window 110 or a front substrate 120 (see FIG. 8) disposed in front of the glass window 110, as described below. Can be.

One example of the plasma display apparatus 100 according to the first embodiment of the present invention is a glass window 110, a rear substrate 130 disposed behind the glass window, as shown in Figs. The phosphor layer 138, a discharge gas (not shown), and a circuit unit 150 are provided.

The rear substrate 130 is spaced apart from the rear of the glass window 110 to form a discharge space between the glass window 110. A plurality of electrodes 121 and 131 are disposed between the rear substrate 130 and the glass window 110. When a predetermined voltage is applied to the electrodes 121 and 131, plasma discharge is generated to generate ultraviolet rays. The phosphor layer 138 is disposed in the discharge space, and ultraviolet rays generated by the plasma discharge collide with each other to emit visible light.

These electrodes may have sustain discharge electrodes and address electrodes. The sustain discharge electrodes 121 are disposed in the discharge cell Ce and may be divided into the scan electrode 122 and the sustain electrode 123 as described below. The scan electrode 122 and the sustain electrode 123 are transparent electrodes 122a and 123a made of a transparent material to pass visible light, respectively, and bus electrodes 122b and 123b made of a metallic material to increase electrical conductivity of the transparent electrode. ) May be provided. If the plasma display device includes transparent electrodes 122a and 123a, and the transparent electrode is disposed on the rear side of the glass window in which the image is implemented, it is preferable that a transparent electrode such as ITO is used to easily transmit visible light. On the other hand, if the sustain discharge electrodes 121 are not disposed in the discharge cell Ce but are disposed in the partition wall 137, the transparent electrodes 122a and 123a may be unnecessary.

The sustain discharge electrodes 121 and the address electrodes 131 may be buried by the dielectric layers 125 and 135, respectively. When the address electrodes 131 are formed over the rear substrate 130, the address electrodes 131 may be covered by the rear dielectric layer 135, and the phosphor layer 138 may be formed on the rear dielectric layer 135. have. In addition, when the sustain discharge electrodes 121 are formed on the rear surface of the glass window 110, the sustain discharge electrodes 121 may be covered by the front dielectric layer 125. In this case, the dielectric layers 125 and 135 may induce charges while preventing cations or electrons from colliding with the sustain discharge electrode 121 and / or the address electrode 131 and damaging the electrodes during discharge. The dielectrics are PbO, B ₂ O ₃ , SiO _2, and the like.

Alternatively, the address electrodes 131 may not be disposed in contact with or adjacent to the front surface of the substrate, and the electrodes disposed in contact with or adjacent to the rear surface of the glass window 110 may serve as address discharge and sustain discharge.

A partition wall 137 may be formed between the glass window 110 and the rear substrate 130. The partition wall 137 partitions the discharge cells Ce together with the glass window 110 and the rear substrate 130. Function.

A protective film 127 may be formed on the rear surface of the front dielectric layer 125, and the protective film 127 may protect the front dielectric layer 125 and emit secondary electrons to facilitate the discharge.

The phosphor layer 138 includes a component that emits visible light by receiving ultraviolet rays emitted by a sustain discharge, which will be described later. The red phosphor layer formed on the red light emitting subpixel is formed of a phosphor such as Y (V, P) O ₄ : Eu or the like. Wherein the green phosphor layer formed on the green light emitting subpixel includes phosphors such as Zn ₂ SiO ₄ : Mn, YBO ₃ : Tb, and the like, and the blue phosphor layer formed on the blue light emitting subpixel includes phosphors such as BAM: Eu and the like. do.

The glass window 110 and the back substrate 130 are preferably coupled and sealed by a coupling member such as frit 139. The glass window 110 and the rear substrate 130 are not necessarily coupled by a coupling member such as frit. When the discharge gas in the cells Ce is in a vacuum state, it may be combined at a pressure according to the vacuum state. On the other hand, inside the discharge cells (Ce) discharges made of any one or two or more of these mixtures of neon (Ne), helium (He), or argon (Ar) including xenon (Xe) gas of about 10% The gas is filled. The rear substrate 130, the glass window 110, the electrodes 121 and 131, the phosphor layer 138, and the discharge gas are formed to form one plasma display panel.

In this case, the electrodes 121 and 131 are connected to the circuit unit 150 for applying a voltage to them. The circuit unit 150 transmits an electrical signal to the electrodes through the signal transmission member 180. The signal transmission member 180 may be a flexible circuit board such as a tape carrier package (TCP), a chip on film (COF), or the like. In this case, the signal transmission member 180 may be packaged by mounting at least one mounting element on each of the tape-shaped wiring units.

On the other hand, at least a portion of the circuit unit 150 is preferably supported by the frame 113 to protect the glass of the glass window. In the glass window 110, a frame 113 is disposed at an edge. By storing a portion of the circuit unit 150 in the ordinary frame 113 supporting the glass window, the circuit unit 150 is not exposed to the outside. As a result, the circuit unit 150 is protected from the outside and excellent in appearance, and a separate member for accommodating and supporting the circuit unit 150 is not required, thereby reducing the material cost.

In this case, the frame 113 is made of a metal material, and a coupling member 115 made of a metal material such as a metal clip is provided at a position supporting the circuit part 150 of the frame 113, and the circuit part ( By being coupled to the coupling member 115 to the frame 113, it is possible to prevent the EMI phenomenon from the circuit unit 150. In this case, a grip member that does not conduct electricity may be disposed on the handle portion of the glass window. Alternatively, the frame 113 may be made of a nonmetal material such as wood or plastic.

On the other hand, in order to smoothly discharge the heat generated from the back substrate 130 to the outside, the heat transfer member 140 may be installed on the rear substrate. The heat transfer member 140 is preferably formed of a metal plate and in contact with the circuit unit 150. The metal plate may smoothly discharge heat from the rear surface of the rear substrate 140 to the outside. This is because it also functions to prevent EMI generated in the circuit unit 150.

 In this case, the back substrate 130 is formed behind the left end or the right end of the glass window 110, and the circuit unit 150 for applying a voltage to the electrodes extending left and right among the electrodes 121 and 131. At least a portion of the glass window 110 may be installed and supported by the frame 113 disposed at the left end or the right end of the glass window 110.

The plasma display device may be a direct current (DC) type, an alternating current (AC) type, a hybrid type (Hybrid) type, etc., depending on the driving method thereof, and a counter discharge type, a surface discharge type, etc. may be used according to the discharge structure. have. In order to drive the plasma display panel having such a structure, the gray level necessary for displaying an image is realized by adjusting the number of sustain discharges according to the video data, and one frame is typically discharged to express the gray level. An ADS (Address and Display period Separated) method may be used, which is divided into several subfields having different numbers of times. In this case, each subfield may be further divided into a reset period for uniformly discharging the discharge, an address period for selecting the light emitting cells to emit light, and a sustain period for expressing gray levels according to the number of discharges.

In particular, in the address period, an address discharge is generated between the electrodes as a period for selecting a discharge cell in which visible light is to be generated, and in the sustain period, sustain discharge is generated so that the visible light is actually generated in the discharge cell. Therefore, a plurality of electrodes are required for the sustain discharge and the address discharge, and the electrodes may include the address electrode 131 and the sustain discharge electrodes 121.

As shown in FIG. 3, the glass window 110 may be disposed on the front surface to allow an image to be emitted to the outside, and the rear substrate 130 may be located behind the glass window 110. In other words, for example, the glass window may be disposed toward the living room rather than the substrate. In this case, the sustain discharge electrodes 121 may be formed in contact with or adjacent to the rear surface of the glass window 110, and may be divided into scan electrodes 122 and sustain electrodes 123, as described below. Can be. The address electrodes 131 may be formed in contact with or adjacent to the front surface of the back substrate 130. In this case, since the light transmittance does not need to be considered, the selection of electrode materials is wide, and electrical Ag, Cu, Cr or the like having high conductivity is preferably used.

The circuit unit 150 may include an address circuit unit 153 and a sustain circuit unit 152. The address circuit unit 153 is connected to the address electrodes 131 and functions to apply a voltage to the address electrodes 131. The sustain circuit unit 152 is connected to the sustain discharge electrodes 121 to apply a voltage to the sustain discharge electrodes 121. The sustain circuit unit 152 is connected to scan electrode lines to supply voltage to the scan electrode 122. It may be provided with a Y circuit portion (152Y) for applying a and an X circuit portion (not shown) connected to the sustain electrode lines to apply a voltage to the sustain electrode 123.

In this case, since the sustain discharge electrodes 121 are extended to the left and right, and the address electrodes 131 are extended to the top and bottom, the sustain electrodes 121 are supported by the frame 113 disposed at the left edge or the right edge of the glass window 110. Preferably, the electrodes are sustain discharge electrodes 121.

In this case, the address chassis member 163, which supports and stores the address circuit unit 153 for applying voltage to the address electrodes 131, may be arranged to be coupled to the glass window 110 by the coupling member 165. . The address chassis member 163 is made of a material having excellent thermal conductivity and is brought into contact with a portion of the address circuit portion 153 so that the columns of the address circuit portion 153 can be smoothly moved to the outside through the address chassis member 163. Can be released. In addition, the address chassis member 163 is made of a metal material and a part thereof contacts the address chassis member 163 through a metal coupling member 165 to prevent the EMI phenomenon generated from the address circuit unit 153. You can block it.

In this case, although not shown, the circuit unit 150 may include an image processor, a logic controller, an address driver, an X driver, a Y driver, a power supply, and the like, and the frame 113 or the address chassis member. The circuit portion supported by 163 may be at least one of these. That is, the address driver or the X driver or the Y driver may be supported by the frame or the address chassis member, and the image processor, the logic controller, and the power supply may be installed on the floor away from the plasma display device.

Alternatively, all of the driving units, the image processing unit, the logic control unit, and the power supply unit may be supported by the frame 113 or the address chassis member 163.

The image processor converts an external analog image signal into a digital signal to generate internal image signals, for example, 8-bit red, green and blue image data, clock signals, and vertical and horizontal synchronization signals. The logic controller generates driving control signals according to an internal image signal from the image processor. The address driver processes an address signal among driving control signals from a logic controller to generate a display data signal, and applies the generated display data signal to the address electrodes 131. The X driver processes the X driving control signal among the driving control signals from the logic controller and applies the X driving control signal to the sustain electrodes 123. The Y driving unit processes the Y driving control signal among the driving control signals from the logic controller and applies it to the scan electrodes 122.

The power supply unit generates and supplies an operating voltage required by the image processor and the logic controller, and an operating voltage required by the address driver, the X driver, and the Y driver.

Meanwhile, in the present invention, as shown in FIGS. 6 and 7, it is preferable that a constant voltage having a constant magnitude is applied to the sustain electrodes 123_1: 123_m through a reset period address period and a driving period to the sustain period. More preferably, the constant voltage applied to the sustain electrodes 123_1: 123_m is a ground voltage Vg. That is, when a constant constant voltage, in particular, a ground voltage is applied to all the sustain electrodes, a separate X circuit part for driving the sustain electrodes 123_1: 123_m is unnecessary as shown in FIG. A separate chassis member for supporting and storing the X circuit portion becomes unnecessary, and as a result, the manufacturing process is simplified, the manufacturing cost is reduced, and the appearance is excellent.

 An example of applying ground voltages to the sustain electrodes 123_1: 123_m will be described with reference to FIG. 7. As shown in FIG. 7, in the driving method basically applied to the plasma display apparatus, the reset period PR, the address period PA, and the sustain period PS are sequentially performed to form one subfield SF. do. First, a driving signal applied to the scan electrodes 122_1: 122_m in the reset period PR will be described. The sustain discharge voltage Vs may be applied to the scan electrodes 122_1: 122_m having the ground voltage Vg applied thereto. ) Is rapidly applied. Thereafter, a rising ramp signal is applied to the scan electrodes 122_1: 122_m by rising from the sustain discharge voltage Vs by a predetermined voltage Vset to reach the highest rising voltage Vs + Vset. The weak discharge is executed by this rising ramp signal, and as a result, negative charges start to accumulate in the vicinity of the scan electrodes 122_1: 122_m. Thereafter, the sustain discharge voltage Vs is rapidly applied to the scan electrodes 122_1: 122_m, and a falling ramp signal falling from the sustain discharge voltage Vs to the lowest falling voltage Vnf is applied. Here, the ground voltage Vg is applied to the sustain electrodes 123_1: 123_m to maintain the ground state.

As a result of the continuous drop of voltage applied to the scan electrodes 122_1: 122_m, a discharge occurs, and as a result, some of the negative charges accumulated in the scan electrodes 122_1: 122_m are emitted. This means that an appropriate level of negative charge remains in the vicinity of the scan electrodes 122_1: 122_m to generate an address discharge. Meanwhile, a constant voltage, for example, a ground voltage Vg, is applied to the sustain electrodes 123_1: 123_m and the address electrodes 131_1: 131_n during the reset period PR. Through such a reset period PR, the charge states of all the discharge cells become uniform.

Next, a predetermined wall voltage is generated in the selected discharge cells in the address period PA. In more detail, the scan pulses of the scan low voltage Vscl are sequentially applied to the scan electrodes 122_1: 122_m biased with the scan high voltage Vsch, and the address electrodes 131_1: 131_n) is applied with an address signal. The address signal applied to each of the address electrodes 131_1 and 131_n is applied with the address voltage Va when the discharge cell is selected, and with the ground voltage Vg otherwise. Meanwhile, the ground voltage Vg is continuously applied to the sustain electrodes 123_1 and 123_m after the reset period PR. In the selected discharge cells, the address voltage Va applied to the address electrodes 131_1 and 131_n, the scan low voltage Vscl applied to the scan electrodes 122_1 and 122_m, and the scan electrodes 122_1 and 122_m are nearby. The address discharge is performed by the wall voltage caused by the accumulated negative charge and the wall voltage caused by the positive charge accumulated near the address electrodes 131_1: 131_n. As a result of the address discharge, positive charges are accumulated near the scan electrodes 122_1: 122_m and negative charges are accumulated near the sustain electrodes 123_1: 123_m.

In the sustain period PS, a predetermined sustain pulse is applied to the scan electrodes 122_1: 122_m, whereby discharge cells in which the wall voltage is accumulated cause sustain discharge. That is, the sustain pulses having the positive sustain discharge voltage Vs and the negative sustain discharge voltage (-Vs) are alternately applied to the scan electrodes 122_1 and 122_m, thereby applying the scan electrodes to the wall voltage formed by the address discharge. When the sustain discharge voltage Vs applied to 122_1: 122_m overlaps and the discharge start voltage or more is applied, the discharge is performed. Meanwhile, during the sustain period, a ground voltage Vg is applied to the sustain electrodes 123_1: 123_m and the address electrodes 131_1: 131_n to maintain a ground state.

As a result, the built-in plasma display apparatus 100 according to the present invention does not need to be provided with an X circuit for driving the sustain electrodes 123.

On the other hand, the built-in plasma display device 100 according to the first embodiment of the present invention is preferably a structure that is driven in a single scan method. When addressed by the single scan method, unlike the dual scan method, by implementing the single scan mode by scanning the scan line in a specific direction, it is possible to reduce the development cost of the circuit part required for driving the plasma display device. It is because the effect of reducing the amount of components is easy to thin, especially when the built-in plasma display device in the glass window.

When driving the address electrodes 133 having lines formed up and down in a single scan method, the address circuit unit 153 may be disposed only above or below the address electrode 133. In this case, it is preferable that an address chassis member 163 (see FIG. 3) for supporting and accommodating the address circuit unit 153 is disposed in combination with the glass window 110 (see FIG. 3).

On the other hand, when addressing the address electrodes 131 having lines formed to the left and right by a single scan, the address circuit unit 153 may be supported by the frame 113 formed at the left or right end of the glass window.

By the plasma display apparatus 100 having such a structure, since the chassis base 40 (refer to FIG. 1) provided in the conventional plasma display apparatus is not provided, the process of manufacturing the chassis base in the plasma display apparatus is eliminated. In addition, the material cost can be reduced by eliminating the need for the chassis base 40 (see FIG. 1) and the adhesive member 35 (see FIG. 1) for bonding the chassis base and the panel.

In addition, since the rear substrate 130 is directly exposed to the outside, heat generated in the rear substrate 130 can be directly cooled by air, so that a separate heat dissipation means is unnecessary. Moreover, in the related art, many structures are required so that the plasma display device can be hung on a wall. However, according to the present invention, such a wall support structure is unnecessary.

Meanwhile, referring to FIGS. 8 and 9, which show modifications of the first preferred embodiment of the present invention, the front substrate 120 is disposed in front of the glass window 110, and visible light for realizing the image is provided. It may be emitted to the outside through the front substrate 120. In this case, the sustain discharge electrodes 221 may be disposed in contact with or adjacent to the rear surface of the front substrate 120, and the address electrodes 231 may be disposed in contact with or adjacent to the front surface of the glass window 110.

In this case, in order to smoothly discharge heat generated between the front substrate 120 and the glass window 110 to the outside, a heat conductive member 240 may be installed on the rear surface of the glass window 110. The heat conductive member 240 is a thin metal plate, and the metal plate is preferably formed to be in contact with at least part of the circuit unit 250.

The structure and function of the address circuit section 253, the sustain circuit section 252, the address electrodes 231, the sustain discharge electrodes 221, the phosphor layer 238, the protective film 227, and the discharge gas are described in the present invention. Since the function and structure of the address circuit unit 153 and the like provided in the plasma display device according to the first embodiment are the same, a detailed description thereof will be omitted.

In addition, the address electrodes 231 are preferably driven in a single scan method, whereby the address circuit unit 253 for driving the address electrodes is disposed on one of the upper side and the lower side of the address electrodes 231, and the coupling member ( 265 is preferably supported by the address chassis member 265.

On the other hand, a portion of the circuit unit 250 is preferably coupled to the coupling member 115 is supported by the frame 113. In this case, the sustain electrode line is preferably applied with the ground voltage throughout the reset period, the address period, and the sustain period, and therefore, the circuit portion supported by the frame 113 is preferably the Y circuit portion 252Y. When the voltages of the storage electrode lines are applied as the ground voltage, the detailed description thereof will be omitted as shown in FIG. 7.

Meanwhile, as shown in FIGS. 10 and 11, in another aspect of the present invention, the plasma display apparatus 300 according to the second preferred embodiment is built in the mirror 310. That is, the plasma display apparatus 300 built in the mirror 310 may include a substrate 390, a mirror 310, a plurality of electrodes 321 and 331, a phosphor layer 338, a discharge gas (not shown), and the like. The circuit unit 350 is provided.

In general, the mirror 310 is coated with mercury on a back surface of a flat glass plate and coated with podium to prevent moisture thereon. Generally, a glass substantially the same as a substrate is used as an address material. Therefore, by building in the plasma display panel to the mirror 310, the same effect as that of the plasma display apparatus built in the glass window can be obtained.

Therefore, in the plasma display apparatus 300 according to the second embodiment of the present invention, the mirror 310 is used as a rear substrate, and the substrate 390 is spaced apart in front of the mirror 310 to thereby provide a mirror. A plasma display device built in 310 may be manufactured.

Alternatively, as a modification of the plasma display apparatus 300 according to the second embodiment of the present invention, although not shown, the mirror may be used as the front substrate, and the rear substrate may be spaced apart from the rear of the mirror. . In this case, after the mercury is removed on the rear surface corresponding to the rear substrate of the mirror, the sustain discharge electrodes 321 may be formed.

The substrate 390 is spaced apart in front of or behind the mirror 310 to form a discharge space between the mirror 310 and the mirror 310.

A plurality of electrodes 321 and 331 are disposed between the substrate 390 and the mirror 310. When a predetermined voltage is applied to the electrodes 321 and 331, plasma discharge is generated to generate ultraviolet rays. The address electrodes 331 and the sustain discharge electrodes 321 are generally provided. The sustain discharge electrodes 321 may include a sustain electrode 323 and a scan electrode 322, and each of the sustain electrode 323 and the scan electrode 322 is a transparent electrode 322a, 323a and a bus electrode, respectively. 322b and 323b.

The electrodes 321 and 331 may be embedded in the dielectric layers 325 and 335. That is, the sustain discharge electrode 321 may be buried in the front dielectric layer 325, and the address electrode 331 may be buried in the back dielectric layer 335. In this case, a protective film 327 may be formed on the rear surface of the front dielectric layer 325.

The phosphor layer 328 is disposed in the discharge space, and ultraviolet rays generated by the plasma discharge collide with each other to emit visible light. The substrate 390 is preferably bonded and sealed by a coupling member such as a frit 339.

Inside the discharge cells (Ce) is discharge gas consisting of any one or two or more of the mixed gas of neon (Ne), helium (He), or argon (Ar) including xenon (Xe) gas of about 10% Is charged.

The circuit unit 350 is for driving the electrodes. The circuit unit 350 may include an address circuit unit 353 for driving the address electrodes 331 and sustain circuit units 352 for driving the sustain discharge electrode 321. It may be stored in the mirror frame 315 for supporting the mirror. Alternatively, the address circuit unit 353 may be coupled to the coupling member 365 to be supported by the address chassis member 363. In addition, at least one of the Y circuit portion 352Y or the X circuit portion 353X may be coupled to the coupling member 365 to be supported by the holding chassis member 367.

In this case, the address electrodes 331, the sustain discharge electrodes 321, the phosphor layer 338, the discharge gas, and the circuit unit 350 are connected to the plasma display device according to the first embodiment of the present invention. Since the components and their functions and structure are the same, the same reference numerals are used, and detailed description thereof will be omitted.

On the other hand, when the mirror 310 is disposed behind the substrate 390, it is preferable that the thermal conductive member 340 having excellent thermal conductivity is attached to the rear surface of the mirror 310, in which case the thermal conductive member is More preferably, the metal is formed to be in contact with the circuit unit 350.

In addition, a voltage is applied to the sustain discharge electrode 321 and the address electrode 331 such that a series of driving cycles including a reset period, an address period, and a sustain period is repeated, and the sustain electrode 323 is provided through the driving period. The voltage applied to) is preferably a constant voltage having a constant magnitude.

In addition, since the address electrodes 331 are preferably driven in a single scan method, the number of circuit parts driving the sustain discharge electrodes 321 and the address electrodes 331 is reduced, and as a result, the circuit part ( The area for mounting the 350 is reduced and the material cost is reduced. Detailed description thereof will be omitted.

As described above, according to the present invention, the plasma display apparatus does not include the adhesive member and the heat dissipation sheet interposed between the plasma display panel and the chassis base. Reduction, manufacturing cost and material cost decrease.

In addition, since the glass substrate is directly exposed to air, high temperature heat generated from the glass substrate can be smoothly released to the outside.

In addition, in order to hang the plasma display device on the wall, a separate member such as a boss or a bracket is unnecessary and excellent in appearance.

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

Claims (29)

sash; A substrate disposed spaced apart in front of or behind the glass window to form a discharge space between the glass window; A plurality of electrodes disposed between the substrate and the glass window and generating plasma discharge therebetween; A phosphor layer disposed in the discharge space and emitting visible light to the outside through the substrate or the glass window according to the plasma discharge; A discharge gas disposed in the discharge space; And A circuit unit for applying a voltage to the electrodes, At least a part of the circuit unit is a built-in plasma display device, characterized in that installed in the frame installed to support the glass window. The method of claim 1, The glass window is a built-in plasma display device, characterized in that the conventional glass window disposed in the living space or office space. delete The method of claim 1, The electrodes are: Address electrodes; And a sustain discharge electrode for generating sustain discharge and an address discharge together with said address electrode in a discharge space disposed between said address electrodes. The method of claim 4, wherein The circuit unit includes a sustain circuit unit for applying a voltage to the sustain discharge electrode and an address circuit unit for applying a voltage to the address electrodes. And at least a portion of the holding circuit portion or the address circuit portion is supported by a frame disposed along an edge of the glass window. The method of claim 5, The holding circuit unit is installed in a frame disposed on the left or right edge of the glass window, And an address chassis member disposed below or above the address electrodes so as to support the address circuit unit. The method according to any one of claims 4 to 6, The address electrodes are formed in contact with or adjacent to the front of the window. The sustain discharge electrodes are formed in contact with or adjacent to the rear surface of the substrate, and the address electrodes and the sustain discharge electrodes are respectively embedded by a dielectric layer, and an image is emitted to the outside through the substrate. Device. The method according to any one of claims 4 to 6, The address electrodes are formed in contact with or adjacent to the front surface of the substrate, the sustain discharge electrodes are formed in contact with or adjacent to the rear surface of the glass window, and the address electrodes and the sustain discharge electrodes are respectively embedded by a dielectric layer. The built-in plasma display device, characterized in that emitted to the outside through the glass window. The method of claim 1, And a voltage is applied to the electrodes in a single scan method. The method of claim 1, And a heat conducting member attached to a surface of the glass window not bonded to the substrate. The method of claim 10, And the heat conductive member is made of a metal material and is in contact with the circuit part. Glass windows installed in living spaces such as residential spaces or office spaces; A front substrate spaced apart in front of the glass window to form a discharge space between the glass window; Barrier ribs disposed between the front substrate and the glass window and defining discharge cells together with the front substrate and the glass window; Sustain electrodes and scan electrodes behind the front substrate, which extend side by side in one direction in which the discharge cells extend; A front dielectric layer covering the sustain electrodes and the scan electrodes; A glass window disposed parallel to the rear of the front substrate; Address electrodes extending in a direction intersecting a direction in which the sustain electrode and the scan electrodes extend from the front of the glass window; A back dielectric layer covering the address electrode; A phosphor layer disposed in the discharge cells; Discharge gas in the discharge cells; An address circuit unit for applying a voltage to the address electrodes; And A Y circuit unit for applying a voltage to the scan electrodes, And the Y circuit portion or the address circuit portion is supported by a frame disposed at the left or right edge of the glass window. Glass windows installed in living spaces such as residential spaces or office spaces; A rear substrate spaced apart from the rear of the glass window to form a discharge space between the glass window; Barrier ribs disposed between the rear substrate and the glass window and defining discharge cells together with the rear substrate and the glass window; Sustain electrodes and scan electrodes behind the glass window, which extend side by side in one direction in which the discharge cells extend; A front dielectric layer covering the sustain electrodes and the scan electrodes; Address electrodes extending in a direction crossing the direction in which the sustain electrode and the scan electrodes extend from the front surface of the back substrate; A back dielectric layer covering the address electrode; A phosphor layer disposed in the discharge cells; Discharge gas in the discharge cells; An address circuit unit for applying a voltage to the address electrodes; And A Y circuit unit for applying a voltage to the scan electrodes, And the Y circuit portion or the address circuit portion is supported by a frame disposed at the left or right edge of the glass window. The method according to claim 12 or 13, A voltage is applied to the sustain electrode, the scan electrode, and the address electrodes such that a series of driving cycles consisting of a reset period, an address period, and a sustain period is repeated, and the voltage applied to the sustain electrode through the driving period is a constant magnitude. Built-in plasma display device, characterized in that the constant voltage. The method of claim 14, And the constant voltage applied to the sustain electrode is a ground voltage. delete The method according to claim 12 or 13, The Y circuit portion is supported on the frame of the windowpane, And an address chassis member for supporting said address circuit portion. The method of claim 17, And the address electrode is driven by a single scan method. mirror; A substrate disposed spaced apart in front of or behind the mirror to form a discharge space between the mirror; A plurality of electrodes disposed between the substrate and the mirror to generate plasma discharge therebetween; A phosphor layer disposed in the discharge space to emit visible light to the outside through the substrate or the mirror according to the plasma discharge; A discharge gas disposed in the discharge space; And A circuit unit for applying a voltage to the electrodes, At least a portion of the circuit portion is a built-in plasma display device, characterized in that installed in the mirror frame for supporting the mirror. The method of claim 19, The electrodes are: Address electrodes; And a sustain discharge electrodes for generating an address discharge and a sustain discharge together with said address electrode in a discharge space disposed between said address electrodes. The method of claim 20, The sustain discharge electrodes are built-in plasma display apparatuses including sustain electrodes and scan electrodes extending in parallel in one direction from the rear of the substrate. The method of claim 21, A voltage is applied to the sustain electrode, the scan electrode, and the address electrodes such that a series of driving cycles consisting of a reset period, an address period, and a sustain period is repeated, and the voltage applied to the sustain electrode through the driving period has a constant magnitude. A built-in plasma display device, characterized in that the constant voltage. The method of claim 22, And the constant voltage applied to the sustain electrode is a ground voltage. The method of claim 20, The address electrodes are formed in contact with or adjacent to the front surface of the mirror, the sustain discharge electrodes are formed in contact with or adjacent to the rear surface of the substrate, and the address electrodes and the sustain discharge electrodes are respectively embedded by a dielectric layer. A built-in plasma display device, characterized in that emitted to the outside through the substrate. The method of claim 20, The address electrodes are formed in contact with or adjacent to the front surface of the substrate, the sustain discharge electrodes are formed in contact with or adjacent to the rear surface of the mirror, and the address electrodes and the sustain discharge electrodes are respectively embedded by a dielectric layer. A built-in plasma display device, characterized in that emitted to the outside through the mirror. The method of claim 20, The circuit unit includes a sustain circuit unit for applying a voltage to the sustain discharge electrodes and an address circuit unit for applying a voltage to the address electrodes. And the at least part of the holding circuit portion or the address circuit portion is accommodated and supported by the mirror frame. The method of claim 19, And the electrodes are driven in a single scan method. The method of claim 19, And a heat conductive member attached to a surface of the mirror that is not coupled to the substrate. The method of claim 28, The heat conductive member is a metal material, and the built-in plasma display device, characterized in that the contact with the circuit portion.

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