KR20060109783A - Plasma display device - Google Patents

Abstract

A plasma display device is provided to reduce noise by forming cooling holes on a front case or a rear case. A front case(10) includes a window(12) which is formed on a center thereof. A plasma display panel(50) is arranged at a backside of the front case in order to display images. A chassis base(60) is used for supporting the plasma display panel. A rear case(70) is arranged at a backside of the chassis base and is coupled with the front case. A plurality of cooling holes(11a,15a,32a,34a) are formed on the front case or the rear case. One or more of the cooling holes has a predetermined angle to a vertical direction of one of the front and rear cases.

Description

Plasma Display Device

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

FIG. 1B is a cross sectional view along line A-A in FIG. 1A;

1C is a partially cutaway exploded perspective view illustrating a plasma display device according to an embodiment of the present invention.

2 is a view for explaining a cooling hole of the plasma display device according to an embodiment of the present invention.

(Explanation of symbols for main parts of drawing)

10; Front case 20; Electromagnetic wave filter

30; Filter holder 40; Sponge

50; Plasma display panel 60; Chassis base

70; Back case

The present invention relates to a plasma display device, and more particularly to a plasma display device having a cooling hole that can reduce the noise felt by the user.

Plasma display panel (Plasma Display Panel; PDP, mixed with the following panel) is formed by forming an electrode on each of the two substrates facing each other, overlapping to have a predetermined interval, injecting the discharge gas therein and sealing Refers to a flat panel display device.

The plasma display apparatus is formed by forming a plasma display panel, connecting a chassis base for mounting elements, for example, a driving circuit, to the plasma display panel, and assembling a front case and a rear case. do.

Such a plasma display device can be formed thinner than a cathode ray tube (CRT) display device, which occupies a large volume, and thus is suitable for realizing a large screen with a relatively small volume. In addition, the plasma display device does not need to form an active element such as a transistor as compared to other flat panel display devices such as LCDs, and has a general characteristic of wide viewing angle and high luminance.

In the plasma display panel, a number of pixels for displaying a screen are arranged in a matrix form. In the plasma display panel, each pixel is driven in a manner of simply applying a voltage to an electrode, that is, a passive matrix method, without an active element for driving the pixel. The plasma display panel may be classified into a direct current type and an alternating current type according to the shape of the voltage signal for driving each electrode, and may be divided into an opposing type and a surface discharge type according to the arrangement of the two electrodes to which the discharge voltage is applied.

On the other hand, the plasma display device, which is a flat panel display device using the plasma display panel as described above, has a problem in that noise is generated during use, in particular, while displaying an image.

The noise is caused by the discharge of the plasma display panel, the operation of a cooling fan for dissipating heat generated during image display of the plasma display panel to the outside, and the vibration caused by the discharge of the plasma display panel. In addition, when the plasma display panel is an AC type, noise caused by a cyclic change in alternating current flowing through a circuit unit supplying power to the plasma display panel may cause noise of the plasma display apparatus.

Such noise is mainly emitted to the outside through an opening part for cooling the plasma display device. In particular, it is transmitted to the outside through a cooling hole installed in the case for mounting the plasma display panel.

However, since the cooling holes as described above are generally formed perpendicular to the case surface, noise is directly transmitted to the user of the plasma display apparatus.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems of the prior art, and an object of the present invention is to provide a plasma display device having a cooling hole that can reduce noise that a user feels.

The present invention for achieving the above object is formed by forming a cooling hole of the plasma display device at a predetermined angle in the vertical direction of the substrate on which it is formed, or the direction of connecting the shortest distance between the center of the cooling hole and the sound source, so Make it relatively long. That is, the present invention relatively increases the movement path of the noise, thereby reducing the magnitude of the noise felt by the user of the plasma display device.

In the present invention, the plasma display device includes a front case having a window formed at the center to allow a user to view an image; A plasma display panel disposed at a rear side of the front case to implement an image so that a user can view an image through the window; A chassis base supporting the plasma display panel; A rear case disposed at the rear of the chassis base and coupled to the front case, and at least one of the front case and the rear case includes a plurality of cooling holes for internal heat dissipation, and at least one of the cooling holes. At least one of the front case and the rear case is formed at a predetermined angle in the vertical direction of the substrate.

The cooling holes are preferably formed at an angle greater than 0 ° and less than 90 ° in the vertical direction of the substrate on which the cooling holes are formed. More preferably, the cooling holes are perpendicular to the substrate on which the cooling holes are formed. It is formed at an angle of 30 ° or more and less than 90 ° in the direction.

And an electromagnetic wave blocking filter and an electromagnetic wave blocking filter holder interposed between the front case and the plasma display panel, wherein the electromagnetic wave blocking filter holder pressurizes the electromagnetic wave blocking filter against the front part of the front case, and the front case. It may be provided with a fixing portion fixed to the front portion of the inner wall portion connecting the pressing portion and the fixing portion.

It may further include a cooling hole formed in the pressing portion, the fixing portion and the inner wall portion of the filter holder.

The front case includes a front part to which the electromagnetic wave blocking filter and the filter holder are seated; The electromagnetic wave blocking filter and the filter holder is provided with a side portion to prevent the separation, the cooling hole may be formed in at least one of the front portion and the side portion.

A sponge may be further disposed between the pressing portion of the filter holder and the plasma display panel.

In addition, in the present invention, the plasma display device includes a front case having a window formed at the center to allow a user to view an image; A plasma display panel disposed at a rear side of the front case to implement an image so that a user can view an image through the window; A chassis base supporting the plasma display panel; And a rear case disposed at the rear of the chassis base and coupled to the front case, wherein any one of the front case and the rear case has a plurality of cooling holes for internal heat dissipation, and the cooling hole has a center point thereof. And a predetermined angle is formed in the direction of the shortest distance connection of the sound source.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

Like reference numerals in the drawings denote like elements.

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

FIG. 1B is a cross-sectional view taken along the line A-A of FIG. 1A,

1C is a partially cutaway exploded perspective view illustrating a plasma display device according to an embodiment of the present invention.

1A to 1C, a plasma display apparatus according to an embodiment of the present invention includes a front case 10 having a window 12 formed at a center thereof to allow a user to view an image, and the front case 10. And a filter holder 30 which is disposed at the rear of the panel and covers the window 12, and which fixes the electromagnetic wave blocking filter 20 with respect to the front portion 11 of the front case 10. And a plasma display panel 50 disposed behind the filter holder 30, a chassis base 60 supporting the plasma display panel 50, and a rear surface of the chassis base 60. And a rear case 70 coupled with the case 10.

The front case 10 includes a front portion 11 on which the electromagnetic wave blocking filter 20 and the filter holder 30 of the front case 10 are seated, and the electromagnetic wave blocking filter 20 and the filter holder 30. It is provided with the side part 15 which prevents separation. The front part 11 of the front case 10 is formed with a screw fastening portion 13 which is fastened to the fixing part 33 of the filter holder 30 by a screw 35. In addition, a first cooling hole 11a is formed in the front portion 11 of the front case 10, and a second cooling hole 15a is formed in the side portion 15 of the front case 10. have.

The electromagnetic wave blocking filter 20 blocks electromagnetic waves emitted forward from the plasma display panel 50, and is grounded to the ground by a ground line (not shown).

The filter holder 30 is a pressing part 31 for pressing the electromagnetic wave filter 20 against the front portion 11 of the front case 10, the front portion 11 of the front case 10. It is provided with a fixed portion 33, and the inner wall portion 32 connecting the pressing portion and the fixed portion. The filter holder 30 may further include an outer wall portion 34 extending vertically from the fixing portion 33 to improve rigidity of the filter holder 30. In addition, the inner wall part 32 is formed with a third cooling hole 32a through which high-temperature air in the first space S1 can pass, and preferably, a fourth cooling hole is formed in the fixing part 33. Is formed. In addition, when the filter holder 30 includes the outer wall portion 34, it is preferable that the fifth cooling hole 34a is formed in the outer wall portion 34.

As shown in FIG. 1C, the plasma display panel 50 includes an upper plate 51 and a lower plate 52. The upper plate 51 has a transparent front substrate 111 and a lower surface 111a of the front substrate. A discharge sustain electrode pair 112 having a complementary structure having a Y electrode 114 and an X electrode 113 as discharge sustain electrodes formed thereon, and an upper dielectric layer 115 covering the plurality of discharge sustain electrode pairs 112. Equipped. The upper dielectric layer 115 is preferably covered by a protective layer 116 formed of MgO. The Y electrode 114 includes a first transparent electrode 114a formed of ITO or the like and a first bus electrode 114b for preventing a voltage drop of the first transparent electrode, and the X electrode 113 is also Y. Similar to the electrode 114, the second transparent electrode 113a and the second bus electrode 113b are provided. The first bus electrode 114b and the second bus electrode 113b may include a material having a dark color to improve contrast of the plasma display panel 50.

The lower plate 52 includes a plurality of address electrodes 122 and a plurality of addresses formed on the rear substrate 121, on the upper surface 121a of the rear substrate 121 to intersect the plurality of discharge sustaining electrode pairs 112. A lower dielectric layer 123 covering the electrode 122, a partition wall 124 formed on the lower dielectric layer 123 to define a light emitting cell together with the discharge sustaining electrode pair 112, and applied to an inner surface of the light emitting cell. Phosphors 125R, 125G and 125B. The light emitting cell is defined by two adjacent partitions 124 and one discharge sustaining electrode pair 112.

The periphery (not shown) of the upper plate 51 and the periphery (not shown) of the lower plate 52 facing it are attached to each other by, for example, a sealing member formed of frit, The space between the lower plates is sealed from the outside by the sealing member. The sealing member may be, for example, solidified after the frit in a liquid state is applied between the upper and lower portions of the lower plate.

When the operation of the plasma display panel 50 is briefly described, when an address discharge occurs in a light emitting cell where the address electrode 122 and the Y electrode 114 intersect, a light emitting cell for discharging will be selected, and then the X will be selected. When a predetermined voltage (main discharge voltage) is applied between the electrode 113 and the Y electrode 114, a discharge occurs in the selected light emitting cell. The discharge gas charged in the light emitting cell emits ultraviolet rays by the discharging, and the ultraviolet rays excite the phosphors 125R, 125G, or 125B applied in the light emitting cells. The excited phosphor emits visible light inherent in the phosphor as its energy level drops. In this manner, an image is realized on the plasma display panel 50 by a plurality of light emitting cells emitting visible light. Since the discharge is generated a plurality of times in a relatively short time, a large amount of heat is generated in the plasma display panel 50. Is generated.

The chassis base 60 supports the plasma display panel 50 and the circuit unit 62. In particular, the plasma display panel 50 is attached to the chassis base by a double-sided adhesive tape. The chassis base may include a wall mount (not shown) for hanging the display device on a wall or a leg (not shown) for supporting the display with respect to the ground.

The circuit unit 62 is connected to the plasma display panel 50 by a cable 61 such as a flexible printed cable (FPC).

The rear case 70 is disposed behind the circuit unit 62 and is coupled to the front case. An air inlet 71 is formed at a lower portion of the rear case 70, and an air outlet 72 is formed at an upper portion thereof. Air flows into the internal space defined by the front case and the rear case through the air inlet 71, and absorbs heat emitted from the plasma display panel 50 and the circuit unit 62 in the interior space. It is discharged to the outside through the air outlet (72).

Meanwhile, a sponge 40 may be interposed between the pressing part 31 of the filter holder 30 and the plasma display panel 50. The sponge 40 prevents the plasma display panel 50 from being damaged by directly colliding with and contacting the filter holder. Also, the sponge 40 has a space between the electromagnetic wave blocking filter 20 and the plasma display panel 50. It may be allowed to enter and exit, and may filter the dust contained in the air flowing between the electromagnetic wave blocking filter 20 and the plasma display panel 50.

In addition, although not shown in the drawings, a plurality of cooling holes may be formed in a part of the rear case.

Meanwhile, the functions of the first cooling hole 11a, the second cooling hole 15a, the third cooling hole 32a, the fourth cooling hole 33a, and the fifth cooling hole 34a are as follows.

As shown in FIG. 1B, the case where the filter holder 30 does not include the outer wall portion 34 will be described first. The air between the electromagnetic wave blocking filter 20 and the plasma display panel 50 is heated by the plasma display panel 50 and then moved to the first space S1 through the upper sponge 40. A part of the high temperature air moved to the first space S1 is guided by the inner wall part 32 of the filter holder 30 to the air outlet 72, and the other part is the inner wall of the filter holder 30. After being guided by the front case 10 via the third cooling hole 32a and the second space S2 formed in the part 32, the air is discharged to the outside through the air outlet 72. That is, the path of the discharge of high temperature air increases, so that the hot air is not stagnated in the first space S1, and thus the hot air between the electromagnetic wave filter 20 and the plasma display panel 50 is air. The exhaust port 72 is smoothly discharged, and thus heat generated in the plasma display panel 50 is smoothly discharged. As such, the heat of the plasma display panel 50 is smoothly discharged to prevent image degradation of the plasma display panel 50 and to prevent damage of the plasma display panel 50 due to heat.

Although the heat dissipation of the plasma display panel 50 is improved even when the second cooling hole 32a is formed only on the inner wall 32 of the filter holder 30 as described above, the fixing part 33 of the filter holder 30 is additionally provided. ) Is formed in the third cooling hole (33a), the first cooling hole (11a) is formed in the front portion 11 of the front case 10, or the side portion 15 of the front case (10) When the second cooling hole 15a is formed in the heat dissipation of the plasma display panel 50 is further improved. When the second cooling hole is formed in the fixing part 33 of the filter holder 30, a part of the air introduced into the second space S2 passes through the fourth cooling hole 33a. When the first cooling hole (11a) is formed in the front portion 11 of the front case 10, a part of the air introduced into the second space (S2) is external through the first cooling hole (11a) When the second cooling hole (15a) is formed in the side portion 15 of the front case 10, part of the air introduced into the second space (S2) through the second cooling hole (15a). This is because it is discharged to the outside.

A third cooling hole 32a is formed in the inner wall portion 32 of the filter holder 30, a fourth cooling hole 33a is formed in the fixing portion 33 of the filter holder 30, and the front surface of the filter holder 30 is formed. In the case where the first cooling hole 11a is formed in the front portion 11 of the case 10 and the second cooling hole 15a is formed in the side portion 15 of the front case 10, the plasma display panel ( It is obvious that the heat dissipation of 50) is further improved.

On the other hand, when the filter holder 30 has an outer wall portion 34 for improving the rigidity of the filter holder 30, a part of the hot air moved to the first space (S1) is the filter holder ( Guided by the inner wall portion 32 of the 30 and proceeds to the air outlet 72, the other part of the third cooling hole (32a), the second space (S2) formed in the inner wall portion 32 of the filter holder 30 And, guided by the front case 10 via a gap (G) between the outer wall portion 34 and the front case 10 is discharged to the outside through the air outlet (72). That is, even in this case, the path for discharging the hot air is increased so that the hot air is not stagnated in the first space S1, and thus the hot air between the electromagnetic wave filter 20 and the plasma display panel 50 is high. Is smoothly discharged through the air outlet 72, and eventually heat generated in the plasma display panel 50 is smoothly discharged. As such, the heat of the plasma display panel 50 is smoothly discharged, thereby preventing the image degradation of the plasma display panel 50 and preventing damage to the plasma display panel 50 due to heat.

As described above, the heat dissipation of the plasma display panel 50 is improved even if the third cooling hole 32a is formed only in the inner wall portion 32 of the filter holder 30, but in addition, the filter holder 30 The fourth cooling hole 33a is formed in the fixing part 33, the fifth cooling hole 34a is formed in the outer wall part 34 of the filter holder 30, or the front part of the front case 10. When the first cooling hole 11a is formed in the 11 or the second cooling hole 15a is formed in the side portion 15 of the front case 10, the heat dissipation of the plasma display panel 50 is further increased. Is improved. When the fourth cooling hole 33a is formed in the fixing part 33 of the filter holder 30, a part of the air introduced into the second space S2 passes through the fourth cooling hole 33a. When discharged to the 72 and the fifth cooling hole 34a is formed in the outer wall portion 34 of the filter holder 30, a part of the air introduced into the second space passes through the fifth cooling hole 34a. When the first cooling hole 11a is formed in the front part 11 of the front case, a part of the air introduced into the second space S2 is discharged through the outlet 72 through the first cooling hole 11a. When the second cooling hole 15a is formed in the side portion 15 of the front case, a part of the air introduced into the second space S2 is discharged to the outside through the second cooling hole 15a. Because it becomes.

That is, the third cooling hole 32a is formed in the inner wall part 32 of the filter holder 30, and the fourth cooling hole 33a is formed in the fixing part 33 of the filter holder 30. A third cooling hole is formed in the outer wall portion 34 of the filter holder 30, and a first cooling hole 11a is formed in the front portion 11 of the front case 10, and the front case 10 is formed. When the second cooling hole 15a is formed in the side portion 15 of the, it is obvious that the heat dissipation of the plasma display panel 50 is further improved.

2 is a view for explaining a cooling hole of the plasma display device according to an embodiment of the present invention.

Referring to FIG. 2, the cooling hole 200 of the plasma display apparatus according to the exemplary embodiment may include at least one of the front case 10 and the rear case 70, in particular, the front case 10. It is preferable that the front part 11 and the side part 15 are formed. In some cases, the cooling hole 200 may be formed in the inner wall portion 32, the fixing portion 33, and the outer wall portion 34 of the filter holder 30.

)를 이루며 형성되어 있다. 즉, 상기 냉각 홀(200)은 상기 냉각 홀(200)이 형성되는 기재의 수직한 방향에 0°초과 90° 미만의 각도를 이루며 형성되는 것이 바람직하며, 더욱 바람직하게는 상기 냉각 홀(200)은 상기 냉각 홀(200)이 형성되는 기재의 수직한 방향에 30° 이상 90°미만의 각도를 구비하며 형성된다. The cooling hole 200 has a predetermined angle in a vertical direction of the substrate on which the cooling hole 200 is formed.

) Is formed. That is, the cooling hole 200 is preferably formed to form an angle of less than 0 ° and less than 90 ° in the vertical direction of the substrate on which the cooling hole 200 is formed, more preferably the cooling hole 200 Is formed with an angle of 30 ° or more and less than 90 ° in the vertical direction of the substrate on which the cooling holes 200 are formed.

)를 이루며 형성된다. 즉, 상기 냉각 홀(200)은 그 중심점 및 음원의 최단 거리 연결 방향에 0°초과 90° 미만의 각도를 이루며 형성되는 것이 바람직하며, 더욱 바람직하게는 상기 냉각 홀(200)은 그 중심점 및 음원의 최단 거리 연결 방향에 30° 이상 90°미만의 각도를 구비하며 형성된다. In other words, the cooling hole 200 has a predetermined angle in the direction of connecting the center point and the shortest distance of the sound source.

Are formed. That is, the cooling hole 200 is preferably formed to form an angle of less than 0 ° and less than 90 ° in the direction connecting the center point and the shortest distance of the sound source, more preferably the cooling hole 200 is the center point and the sound source It is formed with an angle of 30 ° or more and less than 90 ° in the shortest distance of the connection direction.

This is to make the movement path of the noise generated in the plasma display device longer.

In more detail, as shown in the drawing, the noise is reflected in the inclined surface of the cooling hole 200 because the cooling hole 200 is formed at a predetermined angle in the vertical direction of the substrate. do. The reflection of the noise is repeated and the noise goes out of the cooling hole 200.

라 가정하면, 상기 소음의 진행 경로는

만큼 증가하게 된다. At this time, the depth of the cooling hole 200, that is, the thickness of the substrate L, the angle that the cooling hole 200 inclined in the vertical direction of the substrate

Assume that the noise propagation path is

Will increase by.

That is, as the distance from the sound source increases, the size of the noise felt by the user decreases due to the characteristic of the noise whose size decreases.

)를 이루도록 형성함으로써, 소음의 진행 거리가 상기 냉각 홀이 기재에 수직한 방향으로 형성되어 있는 경우보다 상대적으로 증가하게 되며, 이에 따라 사용자가 느끼는 소음의 크기는 작게 된다. As described above, in the plasma display apparatus according to the exemplary embodiment of the present invention, the cooling holes 11a, 15a, 32a, 33a, 34a, and 200 are provided in the cooling holes 11a, 15a, 32a, 33a, 34a, and 200. The predetermined angle (in the vertical direction of the substrate to be formed

By forming a), the traveling distance of the noise is relatively increased than when the cooling hole is formed in the direction perpendicular to the substrate, thereby reducing the size of the noise felt by the user.

According to the present invention as described above, the present invention can provide a plasma display device having a cooling hole that can reduce the noise felt by the user.

While the foregoing has been described with reference to preferred embodiments of the present invention, those skilled in the art will be able to variously modify and change the present invention without departing from the spirit and scope of the invention as set forth in the claims below. It will be appreciated.

Claims (10)

A front case having a window formed at the center for allowing a user to view an image; A plasma display panel disposed at a rear side of the front case to implement an image so that a user can view an image through the window; A chassis base supporting the plasma display panel; A rear case disposed at the rear of the chassis base and coupled to the front case; Some of any one of the front case and the rear case is provided with a plurality of cooling holes for internal heat dissipation, And at least one of the cooling holes is formed at a predetermined angle in a vertical direction of at least one of the front case and the rear case. The method of claim 1, And the cooling holes are formed at an angle greater than 0 ° and less than 90 ° in a vertical direction of the substrate on which the cooling holes are formed. The method of claim 2, And the cooling holes are formed at an angle of 30 ° or more and less than 90 ° in a vertical direction of the substrate on which the cooling holes are formed. The method of claim 1, And an electromagnetic wave blocking filter and an electromagnetic wave blocking filter holder interposed between the front case and the plasma display panel. The electromagnetic wave blocking filter holder includes a pressing part for pressing the electromagnetic wave blocking filter against the front part of the front case, a fixing part fixed to the front part of the front case, and an inner wall part connecting the pressing part and the fixing part. Plasma display device. The method of claim 4, wherein And a cooling hole formed in the inner wall portion, the fixing portion, and the outer wall portion of the filter holder. The method of claim 4, wherein The front case may include a front part to which the electromagnetic wave blocking filter and the filter holder are seated; It has a side portion for preventing the electromagnetic wave blocking filter and the filter holder is separated, And the cooling hole is formed in at least one of the front part and the side part. The method of claim 1, And a sponge interposed between the pressing portion of the filter holder and the plasma display panel. A front case having a window formed at the center for allowing a user to view an image; A plasma display panel disposed at a rear side of the front case to implement an image so that a user can view an image through the window; A chassis base supporting the plasma display panel; A rear case disposed at the rear of the chassis base and coupled to the front case; Some of any one of the front case and the rear case is provided with a plurality of cooling holes for internal heat dissipation, And the cooling hole is formed at an angle in a direction connecting the center point and the shortest distance of the sound source. The method of claim 8, And the cooling hole is formed at an angle greater than 0 ° and less than 90 ° in a direction connecting the center point and the shortest distance of the sound source. The method of claim 9, And the cooling hole is formed at an angle of 30 ° or more and less than 90 ° in a direction connecting the center point and the shortest distance of the sound source.

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