KR910007619Y1 - Slot elimination circuit - Google Patents

Abstract

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Description

Spot elimination circuit when powder 'off'

1 is a circuit diagram of the present invention.

2 is a circuit diagram of one embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: Cathymi 3: CRT

5: Microcomputer Q ₁ -Q ₃ : Transistor

RL ₁ : Relay SW ₁ : Power switch

The present invention relates to a spot elimination circuit during a powder 'off' to remove spots generated when the powder is 'off' in a color television and a monitor using a CRT.

Conventionally, since the secondary screen voltage of the flyback transformer is applied to the acceleration beam grid when the powder is 'on', the cathode of the CRT is heated through the CRT drive stage to scan the electron beam to the fluorescent surface, so that the normal scanning is performed, but the powder is 'off' In this case, since the heater of the brown tube has extra heat, the electron beam is continuously radiated, but at this time, a deflection current does not flow in the vertical and horizontal coils, so that the spot cannot be deflected by the extra heat to generate a spot on the fluorescent surface.

In other words, if the power is 'off' in an electronic device using a CRT, the electron beam by the heat of the heater continues to radiate, but the deflection current does not flow, resulting in a spot phenomenon on the CRT surface. The stimulus was a cause of deterioration of the fluorescent surface.

In view of this, the present invention eliminates the spot phenomenon by preventing the electron beam from being emitted by dropping the acceleration beam grid of the CRT to ground potential when the power is 'off' in a CRT or monitor using CRT. It is to be.

That is, the present invention is to prevent the spot phenomenon by dropping the acceleration beam grid of the CRT to which the screen voltage of the flyback transformer is applied and dropping it to the ground potential along with the 'off' operation.

This will be described in detail with reference to the accompanying drawings.

FIG. 1 is a circuit diagram of the present invention. The relay connected to the collector side is controlled by changing the output level P ₁ of the microcomputer 5 by the pressing operation of the power switch SW ₁ to control the driving of the transistor Q ₃ . The driving of (RL ₁ ) and transistor Q ₁ is controlled.

At this time, the main power supply is controlled by the relay RL _{1 to} which the counter electromotive force preventing diode D ₂ is connected, and the acceleration of the CRT 3 is performed on the collector side of the transistor Q ₁ , to which the reverse voltage preventing diode D ₁ is connected to the base. The beam grid 2 is connected and configured.

The luminance signal is amplified by the transistor Q ₂ connected to the resistor R ₁ and the capacitor C ₁ and applied to the cathode 1 of the CRT 3 to generate an electron beam. The acceleration beam grid 2 to which the voltage is applied is configured to control the acceleration of the electron beam.

2 is a circuit diagram of an embodiment of the present invention to control the acceleration beam grid 2 of the cathode ray tube 3 with the transistor Q ₁ as in the present invention, thereby amplifying the luminance signal without removing the spot phenomenon, and thus the cathode 1. By controlling the collector output of the transistor Q ₂ to be applied to the transistor Q ₁ , the spot phenomenon can be eliminated.

In other words, the present invention eliminates the spot phenomenon by preventing the radiation of the electron beam by using the potential at the acceleration beam grid 2 as the ground potential, and in one embodiment, blocks the amplified luminance signal input applied to the cathode 1 to generate the electron beam. By blocking the spot phenomenon is eliminated.

In the present invention, when the initial power switch SW ₁ is 'on', the microcomputer 5 recognizes this and outputs a high level to the output terminal P ₁ to drive the transistor Q ₃ so that the collector side is low level. As a result, the main power supply relay RL ₁ is driven and the transistor Q ₁ connected to the diode D ₁ and the resistor R ₃ is 'turned off'.

When the relay RL ₁ is driven, the main power is turned on in the set, and the set performs a normal function. With the turn-off of the transistor Q ₁ , the acceleration beam grid 2 is applied to the screen voltage of the flyback transformer. As a result, the electron beam accelerates normally.

That is, when the relay RL ₁ is driven to supply the main power of the set, the luminance signal is amplified by the transistor Q ₂ connected with the resistor R ₁ and the capacitor C ₁ , and then the cathode 1 of the CRT 3 is connected. The electron beam is emitted to the fluorescent surface, and the emitted electron beam is accelerated through the acceleration beam grid 2 for accelerating the electron beam, and then the electron beam is normally scanned by the deflection coil through which a deflection current flows.

Therefore, the fluorescent surface of the CRT 3 is subjected to the normal electron beam scanning so that the set performs the normal operation.

After in this way a set is to perform a normal driving pawooeo switch (SW ₁₎ to Let it "off" microprocessor 5 has recognized this output terminal (P ₁₎ the low level thereby output doemeurosseo transistor (Q _3), the in the " turn-off "is a main power supply relay (RL ₁₎ is applied for the low level and at the same time the base of the transistor (Q ₁₎ is stopped the driving transistor (Q _1), it is to be turned on.

At this time, the microcomputer 5 monitors the pressing of the power switch SW ₁ and outputs the high level to the output terminal P ₁ when pressed once (power on) and output terminal P when pressed once more (power off). ₂ ) outputs a low level.

Therefore, if the relay RL ₁ is not driven, the main power is not turned on and the set stops qualitative driving. At this time, the transistor Q ₁ is 'turned on', resulting in the acceleration beam grid 2 being connected to the ground potential. The spot phenomenon is removed from the fluorescent surface of the CRT 3 by not accelerating the scanning electron beam even after the powder 'off' in (1).

That is, when the power is 'off', the spot phenomenon does not occur by turning off the acceleration beam grid 2 to the ground potential by turning the transistor Q ₁ on.

On the other hand, the present invention can be configured as shown in Figure 2 when the power 'on', the output terminal (P ₁ ) of the microcomputer 5 'turns on the transistor (Q ₃ ) to the output of the main power supply relay ( the scanning of the normal electron beam will be written RL ₁₎ and at the same time the driving Sikkim transistor (amplified luminance signal through the transistor (Q ₂₎ by 'turn-off' the Q ₁₎ is applied to the cathode (1).

However, when pawooeo "off" has been by 'turn-on' a and simultaneously stop the driving transistor (Q ₁₎ of the main power-on relay (RL ₁₎ for amplification by the transistor (Q _2), the luminance signal applied to the cathode (1) By blocking the output and simultaneously 'off', no spot phenomenon occurs on the fluorescent surface of the CRT 3.

That is, in the present design, the spot signal is eliminated by blocking the electron beam by controlling the amplified luminance signal output in the same manner as the operation of blocking the electron beam by controlling the acceleration beam grid 2 to which the screen voltage of the flyback transformer is applied.

As described above, the present invention effectively eliminates the spot phenomena generated during the powder 'off' by blocking the emission of the electron beam by dropping the acceleration beam grid to ground potential when the powder is 'off' in a color tube and monitor using a CRT. You can do it.

Claims (2)

In a CRT in which the luminance signal amplified by the transistor Q ₂ is applied to the cathode 1 and the screen voltage of the flyback transformer is applied to the acceleration beam grid 2, the electron beam is connected to the acceleration beam grid 2. and a transistor (Q ₁₎ to cut off the main power supply relay for the transistor (Q ₁₎ (RL ₁₎ and with reciprocal drive transistor (Q ₃₎ which, pawooeo switch the transistor (Q ₃₎ (SW ₁₎ The spot elimination circuit at the time of the power 'off' composed of the microcomputer (5) which controls the driving by means of. The spot elimination circuit according to claim 1, wherein the transistor (Q ₁ ) is configured to connect the coltrecter side between the cathode (1) and the collector side of the transistor (Q ₂ ) and the emitter side is grounded.