KR0179606B1 - Method for preventing aking in crt - Google Patents

Abstract

The present invention relates to a method for preventing arcing of a cathode ray tube by RGB amplification when the television receiver is turned off.A high voltage is not discharged quickly through the CRT anode terminal when the TV power is turned off. In order to eliminate the conventional drawback of shortening the CRT lifespan, there is a method for eliminating the arcing phenomenon occurring in the CRT when the TV main power is turned off. Determining whether to prevent the arcing phenomenon, amplifying R, G, and B gains applied to the heater of the CRT electron gun to a predetermined level when the arcing prevention key input is determined, and amplified R, G Discharges the high voltage remaining at the anode terminal by the B gain, and the high voltage is rapidly discharged In this order, the R, G and B gains applied to the CRT gun when the TV is turned off are amplified by twice the existing level, and the arcing phenomenon caused by the rapid discharge remaining on the CRT anode terminal is not shown. This can be used to extend the life of the CRT.

Description

How to prevent arcing phenomenon of cathode ray tube by R G B amplification when TV receiver power off

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a television receiver (hereinafter referred to as a TV), and more particularly, to an arcing phenomenon, that is, a sound produced by a high voltage remaining at a cathode ray tube (hereinafter referred to as a CRT) anode terminal when the TV is turned off. The present invention relates to a method for preventing arcing of cathode ray tubes by amplifying RGB when the power of a television receiver is turned off to amplify gains of R, G, and B applied to a CRT electron gun.

In general, a TV for receiving and watching a broadcast signal transmitted from a broadcasting station is briefly described with reference to FIG. 1. When a power cord is inserted into an outlet (not shown), a standby power (for example, 5V) is applied to the microcomputer 200. By operating the power key of the key input unit 220, the power supply unit 700 for applying the main power source AC110 / 220V to the FBT 800 and the main power source applied by the power source unit 700 generate high voltage pulses. FBT 800 for supplying B ⁺ power to the processor 300, the microcomputer 200 for controlling the overall operation of the TV by the operation of the key input unit 220, and the data to be processed in the microcomputer 200 Memory 240 for storing the tuner 100, the tuner 100 for receiving the broadcast signal of the channel selected by the tuner voltage output from the microcomputer 200 from the antenna (ANT), and the broadcast received by the tuner 100 An image processor 300 for processing an image signal of a signal; The image amplification unit 320 amplifies the image signal output from the image processor 300 and the vertical of the image signal displayed on the screen of the CRT 400 by the vertical / horizontal synchronization signal processed by the image processor 300. A vertical / horizontal synchronization processor 340 for deflecting a synchronization signal and a horizontal synchronization signal, a CRT 400 for receiving an image signal output from the image amplifier 320 and displaying it on a screen, and the tuner 100. In the voice processor 500 for processing a voice signal of the received broadcast signal, a voice amplifier 520 for amplifying the voice signal processed by the voice processor 500 to a predetermined level, and in the voice amplifier 520 The speaker 600 is largely configured to receive and output the output audio signal.

2 is a schematic view showing an internal structure of a general CRT 400, and FIG. 3 is an exemplary view showing an internal configuration relationship of a general CRT 400, and generates heat by receiving an image amplified R, G, and B signals. The heater 410 to increase the temperature of the cathode 420, the cathode 420 to emit electrons when a voltage is supplied from the heater 410, and the amount of electrons emitted from the cathode 420 to adjust luminance. The control grid 430 modulates the brightness change, and electrons having a charge are supplied by supplying a constant voltage (eg, 10V400V) so that the electrons emitted from the cathode 420 can reach the fluorescent surface 492 of the glass tube 490. An acceleration grid 440 that attracts and accelerates in the axial direction, and a constant voltage (eg, 110 kHz or more) and the secondary acceleration grid 450 which accelerates secondarily, and the electron which is emitted from the cathode 420 and moves toward the fluorescent surface 492 of the glass tube 490 by the repulsive force between electrons (擴散) Focusing axially to create a thinner electron beam, and a constant voltage (e.g., electrons emitted from cathode 420 and accelerated twice through acceleration grid 440, medium acceleration grid 450). : And a constant voltage (e.g., a high-voltage grid 470) for supplying more than 10 Hz and accelerating in the third order to collide with the fluorescent surface 492 of the glass tube An anode terminal 480 is provided to supply a high voltage of 10 kV or more to the aluminum film of the fluorescent tube 492 of the glass tube 490 and discharge the high voltage when the power is turned off.

FIG. 4 is a flowchart illustrating a process in which arcing occurs in a CRT because R, G, and B are constant when the power of a conventional TV receiver is turned off. In FIG. A step 402 of checking whether the main power supply for supplying the power supply is on; and returning to step S401 if the power key is turned off, and turning on the TV if the power key is on (S403); When the TV is turned on, the viewer views the TV on the selected broadcast channel (S404), and checks whether the main power for completing the TV is turned off (S405), and as a result, there is no power key input. To continue watching, returning to step S404, and if there is a power key input, constantly supplying the R, G, and B gains applied to the heaters of the CRT gun (S406), and the R, G, and B gains are constant. When supplied, high voltage remains at the anode terminals. (S407) and, due to the residual high voltage is showing a step (S408) which the arcing occurs.

1 through 4, the power applied to the TV from the power supply unit 700 is in a standby (eg, 5V) state S401.

When the power supplied to the TV from the power supply unit 700 is in a standby state (for example, 5V), the microcomputer 200 checks whether the main power is on (S402).

As a result of the check, if the power key of the key input unit 220 is in the off state, the microcomputer 200 returns to step S401 and maintains the power supplied to the TV from the power supply unit 700 in the standby state.

However, when the main power is turned on by the microcomputer 220 and the power key of the key input unit 220 is turned on, the power source which is in the standby state (for example, 5V) from the power supply unit 700 is the main power source (AC110 / 220V). ) To apply a high voltage pulse to the FBT 800.

The FBT 800 converts the high voltage pulse applied from the power supply unit 700 into the secondary B ⁺ power and applies the image signal to the image processor 300 through a required terminal to turn on the TV (S403), thereby processing the image processing unit 300. The video signal is amplified to a predetermined level via the image amplifier 320 and outputs the video signal to the screen of the CRT 400 through each stage as shown in FIG. 4 so that the viewer can watch (S404).

In addition, the voice signal processed by the voice processor 500 is amplified to a predetermined level by the voice signal through the voice amplifier 520 outputs to the speaker 600, 620 so that the viewer can listen to the voice.

Referring to the process of amplifying by the image amplifying unit 320 and inputting an image signal to the CRT 400 based on FIGS. 3 to 4, the heater 410 of the CRT 400 electron gun is the image amplifying unit 320. In response to the image amplified R, G, B signal is generated to generate heat to increase the temperature of the cathode 420 of the rear end.

That is, the cathode 420 is in the heater 410 When the voltage is supplied, the input electrons are emitted to adjust the amount of electrons emitted through the control grid 430 to modulate the brightness (change in brightness).

The electrons controlled by the control grid 430 pass through the acceleration grid 440. By supplying 110V400V low voltage Attracts electrons with charge and accelerates them primarily in the axial direction, and then transfers the electrons accelerated primarily through the high pressure medium acceleration grid 450 Secondary acceleration by supplying high voltage over 10㎸.

At this time, the secondary accelerated electrons are diffused by the repulsive force between the electrons, but the focusing grid 460 focuses the electrons, so that the electrons are collected in the axial direction and the thin electron beam is directed to the fluorescent surface 492 of the glass tube 490. To the electron through the super-accelerated grid 470 again. The high voltage of 10 kV or more is supplied again to accelerate the third order to collide with the fluorescent surface 492 of the glass tube 490 to reproduce the video signal.

While watching the TV, the microcomputer 200 checks whether the main power is off (S405), and if there is no power key input from the key input unit 220, the microcomputer 200 returns to step S404 to allow the viewer to continue watching the TV. When there is a power key input from the key input unit 220, the R, G, and B signals are constantly supplied to the electron gun (S406), so that a high voltage remains on the anode terminal 480 of the CRT 400 (S407).

When a high voltage remains on the anode terminal 480 (eg, 1 minute long), the main power is turned off after the arcing phenomenon, that is, a click sound, is generated in the CRT 400.

However, in the general TV, the arcing phenomenon occurs because the high voltage remains because the high voltage is not discharged quickly through the CRT anode terminal when the viewer operates the power key of the key input unit, thereby shortening the CRT life. It was a major factor.

The present invention has been made to solve the above-mentioned shortcomings, and for this purpose, the gain of R, G, B applied to the CRT gun when the TV is powered off is amplified to a certain level (for example, twice the existing level). The present invention provides a method for prolonging the life of a CRT by preventing arcing from occurring by quickly discharging remaining in the CRT anode terminal.

The present invention for achieving the above objects, in the method for eliminating the arcing phenomenon generated in the CRT when the TV main power off, check whether the main power is off, if there is a power key input when the main power off Determining whether to prevent arcing, and if there is an arcing prevention key input, amplify the R, G, and B gains applied to the heater of the CRT gun to a predetermined level (e.g., twice the existing level). Providing a method comprising the steps of: rapidly discharging the high voltage remaining at the anode terminal by the amplified R, G, and B gains; and preventing the arcing phenomenon due to the high voltage being rapidly discharged. It is done.

1 is a block diagram schematically showing a typical television receiver.

Figure 2 is a schematic diagram showing the internal structure of a typical cathode ray tube (Cathode-Ray Tube: CRT).

Figure 3 is an exemplary view showing the internal configuration of a typical cathode ray tube (CRT).

4 is a flowchart illustrating a process in which arcing occurs in a cathode ray tube because R, G, and B are constant when the power of a conventional television receiver is turned off.

5 is a flowchart illustrating a method of preventing arcing of a cathode ray tube by amplification of R, G, and B when the television receiver is turned off according to the present invention;

Explanation of symbols on the main parts of the drawings

100: tuner 200: micom

220: key input unit 240: memory

300: Video Processor 320: Image Amplifier

340: vertical / horizontal synchronization processing unit 400: CRT (Cathode-Ray Tube)

410: Heater 420: Cathode

430 control grid

440: Accelerating Grid

450: medium acceleration grid 460: focusing grid

470: high acceleration grid 480: anode terminal

490: glass tube 492: fluorescent surface

500: Sound Processor 520: Voice Amplifier

600,620: Speaker 700: Power

800: FBT (Flyback Transformer) DY: Deflection coil

Hereinafter, the configuration according to an embodiment of the present invention will be described in detail with the accompanying drawings.

5 is a flowchart illustrating a method for preventing arcing of the CRT by R, G, and B amplification when the television receiver is turned off according to the present invention.

In step S501, when the power applied to the TV is in the standby state, checking whether the main power supplying the main power to the TV is on (502), and if the determined power key is off, returns to step S501. If the power key is turned on, the TV is turned on (S503), if the TV is turned on, the viewer is watching the TV on the selected broadcast channel (S504), and the main power for completing the TV is turned off. In step S505, and if there is no power key input, the TV returns to step S504 if there is no power key input. If there is a power key input, the R, G, and B gains applied to the heater of the CRT gun are constant. A step (S506), a high voltage is left at the anode terminal (S507) if the R, G, B gain is constantly supplied, and the arcing phenomenon occurs due to the remaining high voltage (S508) In the step (S505), the main power source If it is determined that the power key input is turned off to determine whether to prevent the arcing phenomenon when the main power is turned off (S506-1), and if there is no arcing phenomenon prevention key input as a result of the determination, the existing step (S506) is performed. If there is an arcing prevention key input, amplifying the gain of R, G, B applied to the heater of the CRT gun to a predetermined level (for example, twice the existing level) (S507-1), and the amplified R, G It is shown that the step (S508-1) to quickly discharge the high voltage remaining on the anode terminal by the B gain, and the step (S509-1) to prevent the arcing phenomenon due to the high voltage is quickly discharged.

Looking at the working state of the present invention made as described above with reference to Figures 1 to 3 and 5 as follows.

The power cord is inserted into the outlet, and the power applied to the TV from the power supply unit 700 is in a standby state (for example, 5 V) (S501).

When the power supplied to the TV from the power supply unit 700 is in a standby state (for example, 5V), the microcomputer 200 checks whether the main power is on (S502).

As a result of the check, when the power key of the key input unit 220 is in the off state, the microcomputer 200 returns to step S501 and maintains the power supplied to the TV from the power supply unit 700 in the standby state.

However, when the main power is turned on by the microcomputer 220 and the power key of the key input unit 220 is turned on, the power source which is in the standby state (for example, 5V) from the power supply unit 700 is the main power source (AC110 / 220V). ) To apply a high voltage pulse to the FBT 800.

The FBT 800 converts the high voltage pulse applied from the power supply unit 700 into the secondary B ⁺ power and applies the image signal to the image processor 300 through a required terminal to turn on the TV (S503), thereby processing the image processing unit 300. The video signal is amplified to a predetermined level via the image amplifier 320 and outputs the video signal to the screen of the CRT 400 through each stage as shown in FIG. 5 so that the viewer can watch (S504).

In addition, the voice signal processed by the voice processor 500 is amplified to a predetermined level by the voice signal through the voice amplifier 520 outputs to the speaker 600, 620 so that the viewer can listen to the voice.

The process of amplifying the image amplification unit 320 and inputting an image signal to the CRT 400 will be described in detail with reference to FIGS. 3 to 4. First, the heater 410 of the CRT 400 electron gun is the image amplification unit 320. In order to generate heat by receiving the R, G, B signal amplified in the image to increase the temperature of the cathode 420 of the rear end.

That is, the cathode 420 is in the heater 410 When the voltage is supplied, the input electrons are emitted to adjust the amount of electrons emitted through the control grid 430 to modulate the brightness (change in brightness).

The electrons controlled by the control grid 430 pass through the acceleration grid 440. By supplying 110V400V low voltage Attracts electrons with charge and accelerates them primarily in the axial direction, and then transfers the electrons accelerated primarily through a high pressure medium acceleration grid 450 to a predetermined voltage or more. Secondary acceleration by supplying high voltage of 10 전압

At this time, the secondary accelerated electrons are diffused by the repulsive force between the electrons, but the focusing grid 460 focuses the electrons, so that the electrons are collected in the axial direction and the thin electron beam is directed to the fluorescent surface 492 of the glass tube 490. To the electron through the super-accelerated grid 470 again. The high voltage of 10 kV or more is supplied again to accelerate the third order to collide with the fluorescent surface 492 of the glass tube 490 to reproduce the video signal.

While watching the TV, the microcomputer 200 checks whether the main power is off (S505), and if there is no power key input from the key input unit 220, the microcomputer 200 returns to step S404 to allow the viewer to continue watching the TV. If there is a power key input from the key input unit 220, it is determined whether an arcing phenomenon is prevented when the main power is turned off (S506-1).

As a result of the determination, if there is no arcing prevention key input, since the R, G, and B signals are supplied to the electron gun constantly (S506), a high voltage remains at the anode terminal 480 of the CRT 400 (S507).

When a high voltage remains on the anode terminal 480 (eg, 1 minute long), the main power is turned off after an arcing phenomenon, that is, a clicking sound, is generated in the CRT 400.

However, as proposed in the present invention, if it is determined whether to prevent the arcing phenomenon when the main power off (S506-1), if there is an arcing prevention key input to the key input unit 220, R applied to the CRT 400 electron gun, The G and B gains are amplified to a predetermined level (for example, twice the existing level) (S507-1) to quickly discharge the high voltage remaining on the anode terminal 480 (S508-1).

Since the high voltage is quickly discharged through the anode terminal 480, the main power is turned off after preventing arcing phenomenon generated in the CRT 400 (S509-1).

As described above, the present invention amplifies the gain of R, G, and B applied to the CRT electron gun when the TV is turned off to twice the existing level, thereby preventing the arcing phenomenon caused by the rapid discharge remaining on the CRT anode terminal. Therefore, it has the effect of extending the life of the CRT.

The present invention has described a method for preventing arcing of a cathode ray tube by RGB amplification when the television receiver is turned off as described in the claims. However, the present invention is not limited thereto, and those skilled in the art have various applications and Modifications will be possible.

Claims (1)

In the method for eliminating the arcing phenomenon occurring in the CRT when the TV main power is turned off, determining whether the main power is off and determining whether to prevent the arcing phenomenon when the main power is turned off when there is a power key input. As a result, if there is an arcing prevention key input, amplifying the R, G, B gain applied to the heater of the CRT gun to a predetermined level, and quickly amplifies the high voltage remaining at the anode terminal by the amplified R, G, B gain. A method of preventing arcing of a cathode ray tube by RGB amplification when a television receiver is powered off in the order of discharging, and preventing arcing due to high voltage being quickly discharged.