KR100581515B1 - Plasma display pannel which operates at low temperature - Google Patents

Abstract

The present invention relates to a plasma display panel (PDP) that normally operates at low temperatures. It supplies constant power to a resistor that has an electrical resistance that varies with temperature. It is assumed that a transistor performing an on / off switching operation performs an on operation according to the magnitude of the current conducted to the resistance element. When the transistor performs an on operation, power is supplied to the heating coil. The heating coil generates heat by using the supplied power and increases the ambient temperature of the PDP by using the heat generated. In this manner, the PDP can operate normally without errors even at low temperatures.

PDP, SMPS, Heating Coil, Heating Mode, Operating Mode, FET

Description

Plasma display pannel which operates at low temperature

1 illustrates a general plasma display panel;

2 shows a heating system according to the invention,

3 is a view showing a heating control unit and a heating coil of the heating control system according to the present invention,

4 illustrates an operation mode control unit according to the present invention; and

5 is a diagram illustrating on / off timings of a heating mode and an operation mode according to the present invention.

Explanation of symbols on the main parts of the drawings

100: Y board 102: SMPS board

104: X board 106: Digital board

200: AC / DC converter 202: rectifier

204: heating system 300: NTC

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display panel (PDP), and more particularly, to a PDP operating normally at a low temperature.

Among flat displays (FPs), which are in the spotlight in the market recently, PDP products have advantages over other types of FPs due to their cost and ease of implementation of large screens.

 Plasma refers to a state in which positive charges (ions) and negative charges (electrons) are mixed in approximately equal amounts to maintain electrical neutrality while performing a function close to free particles. That is, the plasma is a mixture of ions and electrons.

When a strong voltage is applied to the positive and negative electrodes in a vacuum state, the gas inside is activated and then returns to its stable state over time. As described above, the strong and beautiful light emitted from the aurora is called a plasma phenomenon, and the plasma phenomenon is a PDP. Hereinafter, the characteristics of the PDP will be described.

1. PDP is capable of large screen, ultra light and ultra thin display.

2. PDP secures a viewing angle of more than 160 degrees by self-luminous.

3. Provides sophisticated image quality from small text to digital video.

4. Increase presentation effect by expressing video and computer image simultaneously

Since the PDP can be implemented with a large screen, it is used as an advertisement board outside or in a building rather than for home use. Therefore, the environment in which the PDP operates is worse than the environment in which a general TV operates.

In order to satisfy in such a harsh environment, a product that meets Mill specifications should be designed. Most PDP products on the market must satisfy an operating environment of -15 degrees to 40 degrees.

1 shows a general PDP. The PDP includes a Y board 100, an X board 104, a switching mode power supply (SMPS) board 102, and a digital board 106. Hereinafter, each board will be briefly described. The SMPS board 102 is a board that supplies various power sources. In general, the devices constituting the PDP require various voltages (5v, -5v, 25v, 100v ...). Thus, the elements located on the SMPS board 102 generate the voltages required by the elements of the PDP.

The digital board 106 processes an input video signal or a digital signal. In addition, the digital board 106 performs a function of controlling the X board 104 and the Y board 100. The X board 104 and the Y board 100 perform discharge for each discharge cell according to the control command of the digital board 106.

As described above, the PDP is composed of a transformer, an inductor, a semiconductor element, and the like. The transformer, inductor, semiconductor device, etc. normally operate within a predetermined temperature range. That is, normal operation may not be performed at a temperature outside the above temperature range (less than or equal to -15).

However, as described above, since the PDP is easily exposed to an external environment, there is a need for a method in which devices constituting the PDP can operate normally at a temperature outside the temperature range.

An object of the present invention for solving the above problems is to propose an apparatus and method that can operate normally at a temperature other than the temperature range in which the elements constituting the PDP normally operates.

Another object of the present invention is to propose an apparatus and method capable of outputting an error-free image by operating normally at a temperature other than a temperature range in which elements of the PDP normally operate.

A resistance element having an electrical resistance that varies with temperature to achieve the objects of the present invention; A transistor configured to perform an on / off operation according to a magnitude of a current conducted to the resistance element; And a heating coil configured to generate heat by receiving a current when the transistor performs an on operation, and to raise an ambient temperature by using the generated heat.

The resistance element is the plasma display panel, characterized in that the NTC, the heating coil stops heating when the transistor performs the off operation.

Preferably, the transistor performs an on operation when the ambient temperature is less than or equal to the first threshold, and performs an off operation when the ambient temperature is greater than or equal to the first threshold.

A resistance element having an electrical resistance that varies with temperature to achieve the objects of the present invention; A first transistor configured to perform an on / off operation according to the magnitude of the current conducted to the resistance element; And a second transistor for stopping power supplied to a control element when the first transistor performs an off operation.

Supplying a constant voltage to a resistance element having an electrical resistance that varies with temperature to achieve the objects of the present invention; Performing an on / off switching operation according to the magnitude of the current conducted to the resistance element; And generating heat by receiving a current when the on operation is performed, and raising an ambient temperature by using the generated heat.

Supplying a constant voltage to a resistance element having an electrical resistance that varies with temperature to achieve the objects of the present invention; Performing an on / off switching operation according to the magnitude of the current conducted to the resistance element; And stopping the power supplied to the control element when the off operation is performed.

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

The present invention proposes a method of changing the temperature environment by using the heat generated from the heating coil below the temperature at which each device operates normally. In addition, when the temperature of the PDP is less than the set value it is proposed to stop the operation of the elements constituting the PDP. Hereinafter, the maximum temperature for generating heat using the heating coil is called a first threshold value, and the maximum temperature for stopping the operation of the elements is referred to as a second threshold value. Thus, below the first threshold the heating coil generates heat, and below the second threshold the elements stop operating.

2 illustrates a process of transferring AC received from a power source to an SMPS control device according to the present invention. Although FIG. 2 illustrates only necessary configurations in relation to the present invention, it is obvious that other configurations may be added according to a user's setting.

)을 갖도록 정류화 과정을 수행한다.AC delivered from the power (not shown) is transferred to the AC / DC converter 200. The AC / DC converter 200 converts the received AC into DC. In general, the AC / DC converter 200 includes a bridge circuit, and converts AC into DC using the bridge circuit. The DC output from the AC / DC converter 200 is transferred to the rectifier 202. The rectifier 202 stabilizes the received DC. In general, the DC output from the AC / DC converter 200 does not have a fixed DC value but has a predetermined range of values. Therefore, the rectifier 202 is a constant value of the received DC (

The rectification process is carried out to have

는 SMPS 보드를 구성하고 있는 SMPS 제어 소자들로 전달된다. 또한, 상기

는 본 발명에서 제안한 히팅 시스템(204)으로 전달된다. 상기 히팅 시스템(204)은 히팅 제어부와 히팅 코일로 구성된다. 이하 도 3을 이용하여 본 발명에 따른 상기 히팅시스템(204)에 대해 알아보기로 한다. Rectified

Is transferred to the SMPS control elements that make up the SMPS board. Also, the

Is transmitted to the heating system 204 proposed in the present invention. The heating system 204 is composed of a heating control unit and a heating coil. Hereinafter, the heating system 204 according to the present invention will be described with reference to FIG. 3.

The heating control unit of FIG. 3 is composed of a negative temperature coefficieny resistor (NTC) 300, a first resistor 302, a second resistor 308, and an n-type FET 306. The NTC 300 is a semiconductor device in which electrical resistance decreases rapidly as temperature increases.

Hereinafter, the case in which the temperature of the PDP is less than or equal to the first threshold value will be described first, and then the case in which the PDP temperature is greater than or equal to the first threshold value will be described.

에 의한 전류는 히팅 코일(304)로 전달된다. 상기 히팅 코일(304)은 전달받은 전류에 의해 열이 발생된다. 즉, 상기 PDP의 온도가 제1임계치 이하이면, 상기 히팅 코일(304)은 열을 발산한다. 상기 발생된 열은 상기 PDP 주변의 온도를 상승시키게 된다.If the PDP temperature is below the first threshold value, the electrical resistance of the NTC 300 is increased. That is, the electrical resistance of the NTC 300 is relatively larger than the electrical resistance of the first resistor 302. Therefore, the voltage at the point a has a value similar to the above 0V (actually higher than 0V, not 0V). When the voltage at point a has a value similar to 0V, the FET 306 is turned on. That is, the drain D and the source S are connected. therefore,

The current by is delivered to the heating coil 304. The heating coil 304 generates heat by the received current. That is, when the temperature of the PDP is less than or equal to the first threshold value, the heating coil 304 dissipates heat. The generated heat raises the temperature around the PDP.

(실제는

보다 낮은 전압)와 유사한 값을 갖게 된다. 상기 a지점의 전압이 상기

와 유사한 값을 갖게 되면, 상기 FET(306)는 오프 된다. 즉, 상기 드레인(D)과 소스(S)가 오픈된다. 따라서,

에 의한 전류는 히팅 코일(304)로 전달되지 않는다. 상기 히팅 코일(304)은 열을 발산하지 않는다. 즉, 상기 PDP의 온도가 제1임계치 이상이면, 상기 히팅 코일(304)로 전류가 흐르지 않으며, 따라서 열이 발생되지 않는다.If the temperature of the PDP is above the first threshold value, the electrical resistance of the NTC 300 is reduced. That is, the electrical resistance of the NTC 300 is relatively smaller than the electrical resistance of the first resistor 302. Therefore, the voltage at point a is

(Actually

Lower voltage). The voltage at point a

Having a value similar to the FET 306 is turned off. That is, the drain D and the source S are opened. therefore,

The current by is not delivered to the heating coil 304. The heating coil 304 does not dissipate heat. That is, when the temperature of the PDP is greater than or equal to the first threshold value, no current flows to the heating coil 304, and thus no heat is generated.

3 proposes a method of determining whether the heating coil is heated using NTC. However, it is not limited thereto. That is, PTC may be used instead of the NTC according to the user's setting. When the user uses PTC, the FET is replaced with p type. Alternatively, the same effect may be obtained by changing the positions of the resistors constituting the heating controller. In addition, although FIG. 3 proposes a FET that performs a switching function according to an input voltage, it may be replaced by a device that performs a switching function according to an input voltage instead of the FET according to a user's setting. In addition, the heating control unit may be replaced by a device that performs a switching function according to the temperature.

4 illustrates a method for determining an operation mode of an SMPS control element constituting the PDP according to the present invention. That is, a method of stopping the operation of the SMPS control element is proposed when the temperature of the PDP is less than or equal to the second set value. The control element causes an error at temperatures below the operable range. That is, even if the PDP product is not started (Tune On) or is activated, the panel has low discharge characteristics. In addition, due to a malfunction of the control element, a normal screen may not be displayed or, in severe cases, may be damaged. Therefore, FIG. 4 proposes a method of determining an operation time point of the control element.

For reference, the voltage (current) transmitted to the SMPS control element of FIG. 4 is a voltage for starting the SMPS control element. In contrast, the voltage (current) transmitted to the SMPS control device of FIG. 2 is a voltage processed by the SMPS control device while the SMPS control device is activated. That is, the SMPS control device outputs the required voltage by performing a certain process on the voltage delivered in FIG.

보다 낮은 전압인

를 전달받는다. 상기

를 전달받는 과정에 대한 상세한 설명은 생략하기로 한다. 상기

를 이용하여 상기 SMPS 제어소자를 기동한다. 상기 도 4는 제1저항(400) 내지 제4저항(410), NTC(402)와 n타입 FET(406), n 타입 트랜지스터(412)로 구성된다.4 is

Lower voltage

Received. remind

Detailed description of the process of receiving will be omitted. remind

The SMPS control device is started using. 4 is composed of a first resistor 400 to a fourth resistor 410, an NTC 402, an n-type FET 406, and an n-type transistor 412.

(실제는

보다 조금 낮은 전압)가 된다. 상기 b지점의 전압이 상기

와 유사한 값을 갖게 되면, 상기 FET(406)는 오프 된다. 즉, 상기 드레인(D)과 소스(S)가 오픈된다. 상기 드레인과 소스가 오픈되면, c지점의 전압은

가 된다. 상기 c지점의 전압이

가 되면, 상기 트랜지스터(412)의 에미터(E)와 컬렉터(C)는 오프된다. 따라서, 상기 에미터로부터 컬렉터로 전류는 흐르지 않게 되며, 이로 인해 상기 SMPS 제어소자는 기동 전압이 공급되지 않게 된다. 즉, PDP의 주변 온도가 제2임계치보다 낮은 경우 상기 SMPS 제어소자들은 기동하기 않는다.When the ambient temperature of the PDP is lower than the second threshold, the resistance of the NTC 402 increases rapidly. Therefore, the voltage at point b is

(Actually

Slightly lower voltage). The voltage at point b is

Having a value similar to the FET 406 is turned off. That is, the drain D and the source S are opened. When the drain and source are open, the voltage at point c is

Becomes The voltage at point c

, The emitter E and the collector C of the transistor 412 are turned off. Therefore, no current flows from the emitter to the collector, which prevents the SMPS control device from supplying a starting voltage. That is, the SMPS control elements do not start when the ambient temperature of the PDP is lower than the second threshold.

가 된다. 상기 c지점의 전압이

가 되면, 상기 트랜지스터(412)의 에미터(E)와 컬렉터(C)는 온된다. 따라서, 상기 에미터로부터 컬렉터로 전류가 흐르게 되며, 이로 인해 상기 SMPS 제어소자는 기동 전압이 공급된다. 즉, 상기 PDP 주변 온도가 제2임계치보다 높은 경우 상기 SMPS는 기동을 위한 전류를 전달받아 필요한 동작을 수행한다.When the ambient temperature of the PDP is higher than the second threshold, the resistance of the NTC 402 decreases rapidly. Therefore, the resistance at point b becomes 0V (actually a voltage slightly higher than 0V). When the voltage at point b has a value similar to 0V, the FET 406 is turned on. That is, the drain D and the source S are turned on. When the drain and source are turned on, the voltage at point c is

Becomes The voltage at point c

In this case, the emitter E and the collector C of the transistor 412 are turned on. Thus, current flows from the emitter to the collector, whereby the SMPS control element is supplied with a starting voltage. That is, when the ambient temperature of the PDP is higher than the second threshold, the SMPS receives a current for starting and performs a necessary operation.

It is apparent that FIG. 4 can also be used by replacing PTC as shown in FIG. 3. In addition, although FIG. 4 illustrates the SMPS control device, the temperature inside the PDP may be adjusted using other devices according to a user's setting.

5 illustrates an on / off time point of a heating mode and an on / off time point of an operation mode according to the present invention. According to FIG. 5, the on / off time point of the heating mode is 15 degrees, and the on / off time point of the operation mode is 5 degrees. That is, the on / off timing of the heating mode has a higher value than the on / off timing of the operation mode. That is, when the temperature of the PDP is raised by the heating mode for a predetermined time after the control element is activated, the heating of the heating coil is stopped.

This is because when the temperature of the PDP rises to the set temperature by the heating coil, heat generation by the heating coil becomes unnecessary due to heat generation inside the PDP. However, according to the user's setting, the heating mode on / off point and the operation mode on / off point may be set to have the same value. The temperature shown in FIG. 5 may also be set differently according to the user's setting. That is, the user may set different temperatures instead of the 15 degrees and the 5 degrees shown. In this case, NTC having different resistance characteristics can be adjusted by using.

The present invention proposes a method of raising the ambient temperature of the PDP by using a heating coil when the ambient temperature of the PDP is lower than the first threshold. Various errors can be reduced by artificially raising the ambient temperature of the PDP using the heating coil. That is, it is possible to overcome the disadvantage that the normal screen is not displayed due to malfunction of each element when the PDP ambient temperature is low. In addition, the PDP can be used normally even in a harsh environment without using expensive devices.

Although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and the present invention is not limited to the specific embodiments of the present invention without departing from the spirit of the present invention as claimed in the claims. Anyone skilled in the art can make various modifications, as well as such modifications are within the scope of the claims.

Claims (14)

delete delete delete delete A resistance element having an electrical resistance that varies with temperature; A first transistor configured to perform an on / off operation according to a magnitude of a current conducted to the resistance element; And And a second transistor to stop the power supplied to the control element when the first transistor performs an off operation. The method of claim 5, The resistance element is a power supply of the plasma display panel, characterized in that the NTC. The power supply of claim 5, wherein the first transistor performs an on operation when the ambient temperature is greater than or equal to the second threshold value, and performs an off operation when the ambient temperature is less than or equal to the second threshold value. Feeder. delete delete delete delete Supplying a constant voltage to a resistance element having an electrical resistance that varies with temperature; Performing an on / off switching operation according to the magnitude of the current conducted to the resistance element; And Stopping the power supplied to the control element when the off operation is performed. The method of claim 12, And the resistive element is an NTC. The method of claim 12, wherein performing the on / off switching operation comprises: And performing an on operation when the ambient temperature is less than or equal to the first threshold value, and performing an off operation when the ambient temperature is greater than or equal to the first threshold value.

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