KR19990023735U - X-ray protection circuit - Google Patents

Abstract

The disclosed protection circuit stops the operation of the image display device even when the components included in the X-ray detection unit are damaged and the X-rays are not detected from the cathode ray tube, thereby preventing the X-rays from being excessively emitted.

According to the present invention, the voltage detecting means detects whether the level of the rectified and smoothed voltage in the X-ray detector increases above a predetermined level, and when the voltage detecting means detects a predetermined level or more, the power supply unit operates the power supply control unit. It prevents the output of operating power. When X-rays are emitted from the cathode ray tube, the X-rays are detected twice so that X-rays are not emitted from the cathode ray tube and the X-rays are accurately detected even if the resistance of the X-ray detector changes. By stopping the image display device, it is possible to prevent the human body from being damaged by X-rays.

Description

X-ray protection circuit

The present invention relates to an X-ray protection circuit for preventing excessive emission of X-rays from a cathode ray tube in a video display device such as a television receiver and a monitor having a cathode ray tube.

In general, image display devices using cathode ray tubes generate electron beams according to an image signal from an electron gun provided at the neck of the cathode ray tube, and the generated electron beams are deflected in accordance with the vertical synchronization signal and the horizontal synchronization signal, The predetermined image is reproduced by colliding with the fluorescent substance provided in the.

At this time, the cathode ray tube generates X-rays while reproducing a predetermined image.

The generated X-rays are very harmful to the human body, so that the X-rays are not emitted above a predetermined level in the cathode ray tube to prevent the human body from being damaged by the X-rays.

In order to reproduce a predetermined image, the cathode ray tube requires a high voltage of about 24 to 25 KV.

As the high pressure supplied to the cathode ray tube is higher, more beam current flows through the cathode ray tube, thereby increasing X-rays emitted from the cathode ray tube.

Therefore, the image display devices detect the level of the high pressure supplied to the cathode ray tube and stop the operation of the image display device to prevent X-ray emission when the detected high pressure level exceeds the set value.

1 is a conventional protection circuit diagram.

As shown therein, the horizontal deflection integrated device 1 generates a horizontal deflection drive signal according to the horizontal synchronizing signal, and the horizontal output transformer which passes the horizontal deflection drive signal output from the horizontal deflection integrated device 1 ( 2), the high-pressure generating unit 3 for generating a high pressure in accordance with the output signal of the horizontal output transformer 2 and supplying it to the cathode ray tube, and the high-pressure level generated by the high-pressure generating unit 3 is an excessive amount of X-rays An X-ray detector 4 for detecting emission and stopping the horizontal deflection integrated device 1, and a stop control signal generator for generating a stop control signal when the X-ray detector 4 detects an excessive X-ray emission ( 5) a microcomputer 6 for controlling the overall operation of the video display device and stopping the operation of the video display device when the stop control signal generator 5 generates a stop control signal; A power supply control unit 7 for controlling the supply of power in accordance with a control signal output from the emitter 6, and outputting operating power according to the control of the power control unit 7 and supplying it to the horizontal deflection integrated device 1; The power supply part 8 was comprised.

2 is a detailed circuit diagram of a video display device equipped with a conventional protection circuit.

As shown in the drawing, the horizontal deflection integrated device 1 includes an X-ray protection unit 1A and a horizontal driver 1B, and the X-ray detection unit 4 detects an excessive X-ray emission when the X-ray detection unit 4 detects excessive X-ray emission. When the horizontal driver 1B does not operate under the control of 1A and the X-ray detector 4 does not detect the X-ray excessive emission, the horizontal driver 1B operates to output a horizontal drive signal according to the horizontal synchronization signal. do.

The high voltage generator 3 has the horizontal output transformer 2 connected to the base of the transistor Q1 through a resistor R1, and the ground capacitor C1 is connected to the collector of the transistor Q1. The power source B2 + is connected to the connection point so as to be applied through the primary coil of the flyback transformer FBT so that a high voltage is generated in the secondary coil of the flyback transformer FBT as the transistor Q1 is turned on and off.

The X-ray detection unit 4 is connected to the ground capacitor C2 through a diode D1 (D2) in which a tertiary coil of the flyback transformer FBT is connected in parallel, and after the connection point is passed through the resistor R2. A ground capacitor C3, a ground resistor R3, and an input terminal of the X-ray protection unit 1A of the horizontal deflection integrated device 1 are connected.

The stop control signal generator 5 has a connection point between the diodes D1, D2, the capacitor C2, and the resistor R2 of the X-ray detector 4 through the resistor R4 and the ground resistor R5 and the ground. Connected to the capacitor C4, the power source B1 + passes through the resistor R6 and then again through the resistor R7 together with the connection points of the resistors R4 and R5 and the capacitor C4 to the microcomputer 6 Connected to the interrupt terminal.

The power control unit 7 is connected to the ground capacitor C5 and the transistor through the diode D3 and the resistor R9 together with the output terminal of the microcomputer 6 after the power source B1 + is passed through the resistor R8. It was connected to the base of (Q2) and made the control signal output from the collector to transistor (Q2).

The power supply unit 8 has an output transformer T of a switching mode power supply (SMPS) 8A connected to an input terminal IN of the ground capacitor C6 and the regulator 8B through a diode D4. In addition, the connection point is connected to the control terminal CS of the regulator 8B together with the collector of the transistor Q2 through the resistor R10, and the output terminal OUT of the regulator 8B is connected to the ground capacitor C7 and It is connected to the power input terminal of the horizontal deflection integrated device 1.

In the conventional X-ray protection circuit configured as described above, the power output by the operation of the SMPS 8A of the power supply unit 8 is induced from the primary coil of the transformer T to the secondary coil, and induced into the secondary coil of the transformer T. The power is rectified by the diode D4, smoothed by the DC power supply by the capacitor C6, and then applied to the input terminal IN of the regulator 8B and the control terminal of the regulator 8B through the resistor R10 (R10). CS).

Here, assuming that the microcomputer 6 outputs a low potential to the output terminal, since the transistor Q2 of the power supply control unit 7 is turned off, the state in which the high potential is applied to the control terminal CS of the regulator 8B is applied. Will be maintained.

Then, the regulator 8B operates normally and outputs a constant voltage operating power to the output terminal OUT. The output operating power is stabilized by the capacitor C7 and then applied to the horizontal driving integrated device 1 so that the regulator 8B is horizontal. The driving integrated device 1 operates normally.

In this state, the horizontal driver 1B of the horizontal driving integrated device 1 outputs a horizontal driving signal according to the horizontal synchronizing signal, and the output horizontal driving signal passes through the horizontal output transformer 2 and then a high voltage generating unit. It is applied to the base of transistor Q1 via storage R1 of (3).

Then, the transistor Q1 is repeatedly turned on and off, and as the transistor Q1 is turned on and off, the power source B2 + is induced from the primary coil of the flyback transformer FBT to the secondary coil to apply a high pressure to the cathode ray tube. Will be supplied.

The high voltage induced by the secondary coil of the flyback transformer (FBT) is induced into the tertiary coil, and the voltage induced by the tertiary coil of the flyback transformer (FBT) is applied to the diodes D1 and D2 of the X-ray detector 4. Rectified by the capacitors C2 and C3 and low-pass filtered by the resistors R2 and input to the X-ray protection unit 1A of the horizontal driving integrated device 1 converted into a DC voltage.

Here, when the high voltage is normally output from the flyback transformer FBT, the output voltage of the X-ray detector 4 is lower than the X-ray detection voltage preset in the X-ray protector 1A, and the X-ray protector 1A is horizontal. The driver 1B continues to operate normally.

Since the DC voltage smoothed and rectified by the diodes D1 and D2 and the capacitor C2 of the X-ray detector 4 is input to the stop control signal generator 5, a high potential is applied to the input terminal of the microcomputer 6. Is approved.

Then, the microcomputer 6 determines that the high voltage generator 3 normally generates high voltage, and continuously outputs a low potential to the power control unit 7 so that the transistor Q2 is turned off and the power supply unit 8 is turned off. Will continue to supply operating power.

In this state, when the high voltage output from the high voltage generator 3 becomes higher than the set high voltage and emits a large amount of X-rays from the cathode ray tube, the detection voltage of the X-ray detector 4 is higher than the X-ray detection voltage preset in the X-ray protection unit 1A. Becomes high.

Then, the X-ray protecting unit 1A controls the horizontal driver 1B so as not to output the horizontal driving signal.

As such, when the horizontal driver 1B does not output the horizontal driving signal, the transistor Q1 of the high voltage generator 3 is continuously turned off, so that the flyback transformer FBT does not generate a high pressure and emits X-rays from the cathode ray tube. Will not be.

As the high pressure is not generated in the flyback transformer FBT, the X-ray detector 4 outputs a low potential.

As a result, the voltage output from the stop control signal generator 5 to the microcomputer 6 is lowered. As a result, the microcomputer 6 determines the excessive emission of X-rays and stops the operation of the image display device. The high potential is output to the power control unit 7.

The transistor Q2 of the power control unit 7 is turned on according to the high potential output by the microcomputer 6, and the control terminal CS of the regulator 1B flows to the ground through the transistor Q2. Since the potential of CS becomes low, the regulator 1B does not output power to the output terminal OUT, and stops because the operating power is not supplied to the horizontal driving integrated device 1.

However, in the above-described conventional technique, as the resistors R2 and R3 of the X-ray detector 4 are aged for a long time, the X-ray detector 4 may change a voltage lower than the high voltage generated by the high-pressure generator 3. When it detects and outputs, even if a lot of X-rays are emitted from the cathode ray tube by the high pressure which the high voltage generation part 3 generate | occur | produces, the X-ray detection part 4 will output a low voltage, and the X-ray protection part 1A will not operate.

Then, since the horizontal driver 1B continuously outputs the horizontal driving signal, the high-pressure generator 3 continuously outputs a high level of high pressure, so that many X-rays are continuously emitted from the cathode ray tube, which not only damages the human body but also causes damage to the product. There have been various problems such as a decrease in reliability.

Accordingly, an object of the present invention is to provide an X-ray protection circuit that stops the operation of an image display device by accurately detecting a large amount of X-rays emitted from a cathode ray tube even when the resistance of the X-ray detector changes.

1 is a block diagram of a video display device having a conventional protection circuit;

2 is a detailed circuit diagram of a video display device equipped with a conventional protection circuit;

3 is a detailed circuit diagram of a video display device provided with a protection circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

1: integrated element for horizontal deflection 2: horizontal output transformer

3: high pressure generating unit 4: X-ray detecting unit

5: stop control signal generator 6: microcomputer

7: power control unit 8: power supply unit

ZD: Constant Voltage Diode D11: Diode

According to the X-ray protection circuit of the present invention for achieving this purpose, the X-ray detection unit detects whether the level of the rectified and smooth voltage is increased above a predetermined level by a constant voltage diode as a voltage detection means, the level at which the constant voltage diode is set When detecting an abnormality, the power supply controller is operated to prevent the power supply unit from outputting the operating power.

Therefore, according to the present invention, when X-rays are emitted from the cathode ray tube, double detection thereof prevents X-rays from being emitted from the cathode ray tube, and the X-ray emission is accurately detected even when the resistance of the X-ray detector changes. It can stop the device and prevent the human body from being damaged by X-rays.

Hereinafter, the X-ray protection circuit of the present invention will be described in detail with reference to the accompanying drawings of FIG. 3, and the same reference numerals are assigned to the same parts as in the prior art.

3 is a detailed circuit diagram of a video display device provided with a protection circuit diagram of the present invention.

As shown in the drawing, the present invention detects whether the voltage at the connection point of the diodes D1, D2 and capacitor C2 that rectifies and smoothes the voltage induced by the tertiary coil of the flyback transformer FBT is greater than or equal to the set voltage. When the voltage abnormality is detected, the constant voltage diode ZD, which is a voltage detection means for turning on the transistor Q2 of the power control unit 7 and preventing the power supply unit 8 from operating, and the power control unit 7 The diode D11 prevents the power supply from flowing back to the X-ray detector 4.

In the X-ray protection circuit of the present invention configured as described above, as the conventional power supply unit 8 supplies operating power, the horizontal driving integrated device 1 operates so that the horizontal driver 1B outputs a horizontal driving signal and outputs the same. The high pressure generator 3 operates according to one horizontal driving signal to generate high pressure.

When the X-ray detector 4 detects the high pressure generated by the high pressure generator 3 to determine whether to generate a high pressure above the set level, and when it is determined that the high pressure above the set level is not generated, the integrated device for horizontal driving 1 ) Continues to work normally.

When the X-ray detector 4 detects that the high voltage generator 3 generates a high voltage equal to or higher than a set level, the X-ray protection unit 1A of the horizontal driving integrated device 1 operates to operate the horizontal driver 1B. Since the horizontal drive signal is not output and the horizontal driver 1B does not output the horizontal drive signal, the high voltage generator 3 keeps the transistor Q1 off so that no high voltage is generated.

As the high pressure generator 3 does not generate a high pressure, the X-ray detector 4 outputs a low potential, and the stop control signal generator 5 outputs a low potential to be input to the microcomputer 6. The microcomputer 6 stops the operation of the image display device and controls the power control unit 7 so that the power supply unit 8 cannot supply the operating power.

In this operation, when the resistances R2 and R3 of the X-ray detector 4 are aged and fail to accurately detect the high pressure generated by the high pressure generator 3, the high pressure higher than the set level is generated by the high pressure generator 3. Even if it occurs, the X-ray protection unit 1A of the horizontal driving integrated device 1 does not operate, and thus the horizontal driver 1B continuously generates a horizontal driving signal, so that the high pressure generating unit 3 continuously generates a high pressure, It supplies high pressure and emits a lot of X-rays.

At this time, the voltage rectified by the diodes D1 and D2 of the X-ray detection unit 4 and rectified by the capacitor C2 becomes equal to or higher than the constant voltage of the constant voltage diode ZD and becomes conductive. The connection point voltages of the D2 and the capacitor C2 are applied to the base of the transistor Q2 through the constant voltage diode ZD, the diode D11 and the resistor R9 of the power supply control unit 7.

Then, the transistor Q2 is turned on, and the potential of the control terminal CS of the regulator 8B becomes low potential, so that the operation of the regulator 8B is stopped and no operation power is output.

When the regulator 8B does not output the operating power as described above, the operation of the horizontal driving integrated device 1B is stopped and the horizontal driving signal is not output, so that the high pressure generator 3 does not generate high voltage. The X-ray detector 4 outputs a low potential.

As the X-ray detector 4 outputs a low potential, the stop control signal generator 5 outputs a low potential. As a result, the microcomputer 6 stops the operation of the image display device. The low potential is output to (7) to keep the transistor Q2 on.

As described above, the present invention stops the operation of the image display device while the constant voltage diode is in a conductive state when the X-ray detector detects a large amount of X-rays emitted from the cathode ray tube due to a change in resistance. This prevents the human body from being damaged by X-rays emitted from the cathode ray tube.

Claims (3)

A horizontal deflection integrated device which generates a horizontal deflection drive signal according to the horizontal synchronization signal; A horizontal output transformer for passing a horizontal deflection driving signal output by the horizontal deflection integrated device; A high pressure generator for generating a high pressure according to the output signal of the horizontal output transformer and supplying the high pressure to the cathode ray tube; An X-ray detector configured to stop the horizontal deflection integrated device by detecting excessive emission of X-rays at a high voltage level generated by the high-pressure generator; A stop control signal generator configured to generate a stop control signal when the X-ray detector detects an excessive X-ray emission; A microcomputer that controls the overall operation of the image display device and stops the operation of the image display device when the stop control signal generator generates a stop control signal; A power control unit controlling supply of power according to a control signal output from the microcomputer; A power supply unit configured to output operating power to the horizontal deflection integrated device according to the control of the power control unit; When the high voltage generator detects whether the rectified and smooth voltage levels are higher than or equal to a predetermined voltage level and detects an abnormal voltage level, the power control unit controls the power supply to prevent output of operating power. X-ray protective circuit comprising a voltage detection means. The apparatus of claim 1, wherein the voltage detection means; X-ray protective circuit, characterized in that the constant voltage diode. 3. The apparatus of claim 1 or 2, further comprising: the voltage detecting means; And a diode which prevents the voltage from flowing back from the power control unit to the X-ray detector.