KR0183471B1 - Temperature control method of plasma indicating device and the apparatus thereof - Google Patents

Abstract

The present invention discloses a novel method for controlling the temperature of a PDP or a multi-screen device comprising the same and an apparatus for implementing the same.

PDP, which uses relatively high power, is more invented than other flat panel display devices. In particular, a problem caused by overheating of internal modules is severe when configuring a multi-screen device.

The present invention solves the problem of overheating by sensing the temperature of the PDP or its multi-screen device and controlling the power supply accordingly.

Description

Plasma display temperature control method and device

1 is a front view showing the configuration of a PDP multi-screen device.

2 is a block diagram of a temperature control device for implementing the method of the present invention.

3 is a flow chart showing one preferred flow of the method of the present invention.

4 is a cross-sectional view of a module showing one installation method of a temperature sensor.

5 is a partially enlarged front view of a multi-screen device showing another installation method of the temperature sensor.

6 is a cross-sectional view taken along the line VI-VI of FIG.

* Explanation of symbols for main parts of the drawings

10: temperature control unit 11: temperature discriminating unit

12 gate part 13 switching unit

20: heat sensing portion 21: temperature sensor

23: bracket 30: power supply

40: PDP drive unit M, M1, M2: module

P: PDP Panel

The present invention relates to a plasma display device, and more particularly, to a plasma display device, a temperature control method of a multi-screen device using the same, and a device for implementing the same.

Plasma Display Panel (PDP), which realizes high luminance and high image quality, is not only a thin TV or OA device but also recently replaced LED display in the construction of a multi-screen device. It is used.

In FIG. 1, an example of such a multi-screen apparatus using a PDP is illustrated. Modules (M1 and M2) each composed of 2 × 2 PDP panels (P) have 5 × 4 in a cabinet (K). Arranged to form a large multi-screen device. However, since PDP uses a gas discharge phenomenon, a relatively large power consumption image display device using a discharge voltage of several hundred V, which is considerably higher than other flat panel display devices, generates a large amount of heat during use. The problem of heat generation and the resulting temperature rise is particularly prominent in the reflective PDP. In addition, overheating of the panel becomes a problem even in a TV or an OA device using the PDP panel alone, but in a multi-screen device having a large number of panels The problem is even worse.

For example, in the multi-screen device shown in FIG. ) Is easy to overheat, and the problem of temperature rise is serious.

When the PDP panel is overheated, the discharge conditions are different, so that it is difficult to control the display of an appropriate image, the light emission luminance is locally changed, and the electrode and the driving circuit are damaged due to overload, which significantly shortens the service life of the panel. Compared with the front side and the back side of the panel, the front side is exposed to the outside air, so the temperature is lower than the back side, but the cathode side which is vulnerable to overheating or voltage change is located on the front side of the panel. It must be properly managed.

Nevertheless, in the related art, only a cooling fan (not shown) that circulates and cools the inside of the cabinet K as a whole is provided, and a technology for properly controlling the temperature of the panel has not appeared.

It is an object of the present invention to provide a temperature control method capable of preventing overheating and subsequent problems of a plasma display device or a multi-screen device using the same, and an apparatus for implementing the same.

The temperature control method of the present invention for achieving the above object, by measuring the temperature of one or a plurality of locations of the PDP or multi-screen device and controls the supply of power used to drive the PDP when this temperature corresponds to a predetermined condition Characterized in that.

The control of the supply power is made by cutting off the power supply itself or subtracting the voltage or current of the supply power.

Specific features of the temperature control method of the present invention having such a feature and an apparatus for implementing the same will become more apparent from the following description of the preferred embodiments with reference to the accompanying drawings.

2 is a block diagram showing a temperature control device for implementing the method of the present invention. The temperature of the panel is sensed by a temperature sensor 21 installed at one or a plurality of positions of one or more PDP panels. And a temperature controller 10 for controlling the power supply unit 30 for supplying power AC to the PDP driving unit 40 according to the temperature sensed by the heat sensing unit 20. .

The temperature control unit 10 gates each of the determination results of the temperature discriminating unit 11 and the temperature discriminating unit 11 to determine whether the temperature sensed by the temperature sensor 21 of the heat sensing unit 20 is higher than a predetermined temperature. a gate part 12 for determining and outputting the gate part 12 by determining whether it corresponds to a predetermined overheat condition, and a switching part 13 for controlling the power supply of the power supply part 30 according to the output of the gate part 12. It is provided.

Preferably, the temperature discriminating unit 11 includes comparators to which reference voltages corresponding to a predetermined reference temperature are applied to compare the voltage input from the temperature sensor 21 of the heat sensing unit 20 with the reference voltage. The result is output in 0.1 or H, L. The reference temperature set in the temperature discriminating unit 11 may be set to different reference temperatures, for example, for the inner module M2 and the outer module M1 according to the positions of the respective modules M1 and M2.

The gate part 12 is composed of a combination of one or a plurality of gates outputting a predetermined high heat condition by combining the outputs of the temperature discriminating part 11. For example, when any one of the temperature sensors 21 of the thermal part 20 detects overheating, the gate part 12 may include only one OR gate. In addition, when the temperature sensor 21 at a predetermined position and the temperature sensor 21 at another predetermined position detect an overheating at the same time, the gate unit 12 is a combination of OR gates and AND gates or another gate. It can be configured by a combination of these.

On the other hand, the switching unit 13 may be provided with a relay (relay) and / or a variable resistor interlocked to the power supply unit 30 to block or control the power supply according to the output of the gate unit 12, When the power supply unit 30 is configured as a digital device, it has an appropriate switching means for interrupting and controlling it.

Looking at the temperature control device as described above, the temperature control method of the present invention proceeds as shown in FIG.

When the power of the PDP or the multi-screen device using the same is started in step 100 of FIG. 3 and is turned on in step 110, steps 120 through (d) are performed until the power is turned off in step 170. The temperature control process of 160 is continuously repeated.

When the temperature sensors 21 of the heat sensing unit 20 installed at one or a plurality of locations of the PDP or the multi-screen device sense the temperature at step 120, the temperature discriminating unit 11 is detected at step 130. The temperature is compared with the reference temperature set as the reference voltage, and the determination result is output to the gate unit 12.

In step 140, the gate part 12 then combines the outputs of the temperature discriminating part 11. In step 150, if these outputs do not meet the predetermined overheating condition, the process returns to step 120 to continue the temperature sensing, and if the predetermined overheating condition is reached, the process proceeds to step 160 where the switching unit 13 supplies power. After the supply power of the supply unit 30 is controlled, the process returns to step 120 to maintain the control state until the temperature condition of the PDP panel is out of the overheat condition.

Here, the control process of the supply power is made of a process of blocking the power supply itself or controlling the voltage or current of the supply power as described above. If the power supply itself is cut off, the PDP or its multi-screen device stops displaying images until the overheated panel is properly cooled.

On the other hand, if the voltage or current of the power supply is limited to a level lower than a control, for example, a normal driving voltage, the PDP and its multi-screen device operate at a luminance level lower than the normal luminance. Therefore, the level of the controlled power supply must be at least equal to or higher than the level required for discharging the PDP.

When the PDP or the multi-screen device is overheated as described above, the image display is stopped or the image is displayed at a low luminance level, and when it is confirmed that the cooling is sufficiently performed in step 150, the temperature control is continued. When the power is turned off, the temperature control process of the present invention is terminated in step 180.

By this process, the present invention prevents overheating of the PDP and the multi-screen device to ensure normal image display and at the same time ensure a long service life.

Meanwhile, FIGS. 4 to 6 illustrate configurations in which it is preferable to install the temperature sensor 21 of the thermal part 20 on the PDP panel.

First, Figure 4 shows a module (M) constituting a multi-screen device. The module M is constituted by providing one or more PDP panels P and a circuit board B thereof in the frame F. The temperature sensor 21 is installed on the frame F through a support means such as a support sleeve 22 and is configured to sense the temperature of the rear surface of the PDP panel P. In the multi-screen device as shown in FIG. 1, the temperature sensor 21 is preferably installed in each of the plurality of modules M1 and M2 to measure the back temperature of each module M1 and M2 to measure the temperature discriminating unit ( 11) will be notified.

In the configuration of FIG. 4, the temperature sensor 21 is provided on the rear surface of the PDP panel P, and does not interfere with the image display on the front surface. However, the rear side of the PDP panel P has heat generation or cooling such as a circuit board B. The operation of the fan may not adequately represent the temperature of the PDP panel P. Therefore, it is desirable to directly detect the temperature of the front side of the PDP panel P, which is vulnerable to overheating. Therefore, it is very difficult to install the temperature sensor 21 on the front side of the PDP panel P without disturbing image display. .

5 and 6 are structures for overcoming this difficulty and directly measuring the front side temperature of the PDP panel P. As shown in FIG. That is, it is common that the image information is not displayed on the four corners of the PDP panel P or the multi-screen device having the same or the importance of the display information is low. Accordingly, in the embodiment of FIG. 5, by installing a bracket 23 on the front side of the corner portion of the module M located at the corner portion of the multi-screen apparatus, the temperature sensor 21 is supported on the bracket 23. The temperature sensor 21 contacts the front surface of the PDP panel P to measure the temperature of the front side.

This configuration of FIGS. 5 and 6 can preferably be used in combination with the configuration of FIG. In this case, the temperature sensor 21 of the configuration of FIG. 4 senses the back side temperatures of the plurality of modules M, which may represent the inner module M2 and the outer module M1, respectively. The temperature sensor 21 of the configuration shown in Figure 3 is preferably configured to detect the temperature on the front side of each corner of the four modules (M) located in the four corners of the multi-screen device.

As described above, according to the present invention, in the PDP and the multi-screen device using the module as a module, it is possible to prevent local or global overheating, thereby maintaining the image quality and stability of the display image and significantly increasing the service life thereof.

Claims (10)

In a multi-screen device comprising a plasma display device or a plurality of plasma display devices, the plasma display device is driven when the measured temperature corresponds to a predetermined overheating condition by measuring a temperature at one or a plurality of locations of the plasma display device. A temperature control method of a plasma display device, characterized in that for controlling the supply of power used in the. The temperature control method of claim 1, wherein the supply of power is blocked until the control of the power supply is out of the overheating condition. The method of claim 1, wherein the plasma display device is driven at a low luminance until the control of the power supply is out of the overheating condition by limiting the voltage or current of the power supply. . A multi-screen device comprising a plasma display device or a plurality of plasma display devices, comprising: a power supply unit supplying power to the plasma display device, a heat sensing unit sensing a temperature of one or a plurality of positions of the plasma display device; And a temperature control unit for controlling the supply power of the power supply unit according to the temperature sensed by the heat sensing unit. The method of claim 4, wherein the temperature control unit, a temperature discriminating unit for comparing the temperature detected by the heat sensing unit with a predetermined reference temperature and outputs a comparison result, and the output of the temperature discriminating unit corresponds to a predetermined overheat condition And a switching unit for controlling the power supply of the power supply unit according to the output of the gate unit. The method of claim 4, wherein the switching unit comprises a relay and / or a variable resistor to block or limit the power supply of the power supply unit. The method of claim 4, wherein the heat sensing unit includes a plurality of temperature sensors. 8. The method of claim 7, wherein a temperature sensor of the heat sensing part is installed in a frame supporting the plasma display device to measure a back temperature of the plasma display device. 8. The method of claim 7, wherein the temperature sensor of the heat sensitive portion is supported by a bracket provided at a corner of the plasma display device to measure the front surface temperature of the plasma display device. 10. The plasma display device of claim 9, wherein the plasma display device constitutes a multi-screen device, and the temperature sensor of the heat sensing part is supported by a bracket provided at a corner of the plasma display device located at the corner of the multi-screen device. A temperature control method of a plasma display device, characterized in that for measuring the front temperature of the device.