KR100304900B1 - Apparatus for restricting beam current of monitor - Google Patents

Abstract

The present invention relates to a beam current limiting device of a monitor which prevents an increase in beam current abnormality and improves production efficiency, regardless of the operating state of the monitor. In a monitor having a cathode ray tube, a high voltage for driving the cathode ray tube is generated. The flyback transformer, the flyback transformer driving and deflection unit for driving the flyback transformer and the horizontal deflection yoke according to the control signal of the microcomputer, and the G1 voltage of the cathode ray tube according to the G1 voltage adjustment signal to adjust the raster brightness. A raster luminance control unit for controlling the beam current, a beam current limiting unit for controlling the G1 voltage regulation output of the raster luminance control unit according to an increase in the beam current flowing in the high voltage winding of the flyback transformer, and a beam current limiting unit corresponding to an external operation command; The control signal is output to the flyback transformer drive and deflection unit and the G1 to the raster luminance control unit. Since it comprises a microcomputer which outputs a pressure control signal is prevented completely the increase in beam current or more is improved the production efficiency.

Description

Beam current limiter of monitor {APPARATUS FOR RESTRICTING BEAM CURRENT OF MONITOR}

TECHNICAL FIELD The present invention relates to a monitor, and more particularly, to an abnormal beam current limiting device of a monitor.

In general, the beam current is a current flowing through the anode electrode according to the high voltage output of the flyback transformer (FBT), which is proportional to the high voltage of the FBT, the G1 and G2 electrode voltages, and is applied to the R / G / B cathode voltage. It is inversely related and closely related to the amount of X-ray, or Roentgen line, emitted from the monitor.

That is, as the beam current increases, the amount of roentgen wire that adversely affects the human body also increases. According to the FDA standard, the test item for limiting the amount of roentgen radiation emitted from the monitor to 0.1 mR per hour and meeting the FDA standard after completion of the monitor manufacturing IRLC (Isoexposure Rate Limit Curve) test is performed.

Therefore, all monitors are configured with a beam current limiter to limit the generation of Rhentgen lines within the range specified in the FDA standard.

The beam current limiter of the monitor according to the prior art drives the FBT 2 for generating high voltage, the + B voltage and the horizontal deflection yoke HDY for driving the FBT 2 as shown in FIG. FBT drive and deflection unit 1 for generating a horizontal drive pulse for detecting the abnormal increase in the beam current flowing in the high-voltage winding of the FBT (2) and control the R / G / B output voltage level to limit the beam current Raster luminance control unit 4 for controlling the raster brightness by adjusting the G1 voltage of the CDT (Color Display Tube) according to the beam current limiting unit 3, the G1 voltage adjustment signal, the FBT (2) The high voltage detector 5 detects the abnormality of the high voltage output from the secondary winding and outputs a detection signal, and the voltage abnormality of the FBT 2 is detected according to the detection signal output from the high voltage detector 5. The driving and deflection unit 1 is controlled and the raster luminance control unit 4 receives a G1 voltage adjustment signal. It is configured to include a microcomputer 6 for outputting.

At this time, the FBT driving and deflection unit 1 includes a variable resistor VR1 for adjusting the high voltage level of the FBT 2 output, a transistor Q1 for generating + B high voltage for driving the FBT 2, and a horizontal deflection yoke. A transistor Q2 for driving the HDY and a square wave corresponding to the duty ratio set by the variable resistor VR1 according to the control signal of the microcomputer 6 are generated and output to the transistor Q1 and horizontally driven. And a synchronization signal processor 11 for generating a pulse and outputting the pulse to the transistor Q2.

The FBT 2 then has a variable resistor VR2 for adjusting the screen voltage.

The beam current limiter 3 outputs an image preamplifier output gain control signal in proportion to the voltage drop across the resistor R4 caused by the beam current Ib flowing in the high voltage winding of the FBT 2 so that the R / G / And a transistor Q6 for limiting the beam current by lowering the B output voltage level.

The raster luminance control unit 4 amplifies the negative voltage V2 output from the secondary winding of the FBT 2 according to the G1 voltage adjustment signal output from the microcomputer 6 and supplies it to the G1 electrode of the CDT. And three transistors Q4, Q5, and Q8.

The high voltage detection unit 5 divides the voltage divided by the voltage dividing resistor R2 and R3 for dividing the voltage V1 output from the secondary winding of the FBT 2 and the voltage dividing resistor R2 and R3. When the voltage level is above a certain level, the transistor Q3 is turned on to output a high voltage detection signal having a 'low' level to the microcomputer 6.

The beam current limiting operation of the prior art configured as described above will be described.

First, when the monitor power is 'on', the microcomputer 6 outputs a control signal to the FBT driving and deflection unit 1 and outputs a G1 voltage adjustment signal to the raster luminance control unit 4.

According to the control signal of the microcomputer 6, the synchronization signal processing unit 11 of the FBT driving and deflection unit 1 generates a square wave corresponding to the duty ratio set by the variable resistor VR1 to generate the transistor Q1. And a horizontal driving pulse is generated and output to the transistor Q2.

Subsequently, the transistor Q1 supplies the B + voltage to the FBT 2 and the transistor Q2 supplies the horizontal driving pulse to the horizontal deflection yoke HDY so that the FBT 2 outputs a high voltage and a negative voltage V2. .

The raster luminance control unit 4 amplifies the negative voltage V2 output from the FBT 2 according to the G1 voltage adjustment signal of the microcomputer 6 and applies it to the G1 electrode of the CDT.

At this time, in the normal operation state of the monitor, when the high voltage of the FBT 2 does not increase and only the beam current Ib increases, for example, when only 100% white is displayed on the screen, when the beam current Ib increases, 'Ib × R4' 'Voltage drop occurs.

Subsequently, the voltage drop reduces the collector voltage level of the transistor Q6 of the beam current limiter 3, thereby reducing the output gain of the image preamplifier, thereby limiting the beam current by reducing the R / G / B output voltage level. Done.

On the other hand, when the variable resistor VR1 of the FBT driving and deflection unit 1 is shorted during the IRLC test according to the FDA standard, the high voltage level output from the FBT 2 increases, and the beam current increases accordingly.

When the voltage V1 induced in the secondary winding of the FBT 2 rises due to the high voltage output from the FBT 2, when the transistor Q3 of the high voltage sensing unit 5 is turned on, the low signal is received by the microcomputer 6. ) Is entered.

Subsequently, the microcomputer 6 detects an abnormality of the high voltage level and controls the synchronization signal processing unit 11 of the FBT driving and deflection unit 1 to block the output of the square wave and the horizontal driving pulse to perform the high voltage limiting operation and monitor accordingly. The operation is stopped.

However, if the variable resistor VR1 is increased to raise the high voltage level such that the high voltage limiting operation is not performed, the beam current Ib increases in proportion thereto.

At this time, the monitor production process is completed by setting the high voltage level and the beam current to a value that satisfies the IRLC standard, and performing a sealing operation so that the resistance value of the variable resistors VR1 and VR2 cannot be increased to the upper limit. do.

Of course, even at this time, the beam current limiter 3 operates, but merely controls the output gain of the image preamplifier to adjust only the R / G / B output voltage, thereby sufficiently limiting the beam current due to excessive rise of the G1 and G2 electrode voltages. can not do.

The beam current limiting device of the monitor according to the prior art has the following problems.

First, the beam current limit is not fully achieved depending on the monitor operating state, which causes an increase in Rhentgen line.

Second, since the variable resistance, that is, the high-pressure volume and the screen voltage volume sealing process must be performed to limit the beam current after the production, the overall production process is complicated and the time required increases and the production efficiency is lowered.

Accordingly, an object of the present invention is to provide a beam current limiting device for a monitor which can prevent an increase in beam current abnormality and improve production efficiency regardless of the operating state of the monitor. There is this.

1 is a circuit diagram showing the configuration of a beam current limiter of a monitor according to the prior art

Figure 2 is a circuit diagram showing the configuration of the beam current limiting device of the monitor according to the present invention

Explanation of symbols for main parts of the drawings

21: FBT drive and deflection 22: FBT

23: beam current limiter 24: raster brightness control unit

25: high voltage detection unit 26: microcomputer

31: synchronization signal processing unit

The present invention relates to a monitor having a cathode ray tube, comprising: a flyback transformer for generating a high voltage for driving a cathode ray tube, a flyback transformer for driving a flyback transformer and a horizontal deflection yoke according to a control signal of a microcomputer; A raster luminance control unit controlling raster brightness by adjusting the G1 voltage of the cathode ray tube according to the G1 voltage adjustment signal, and adjusting the G1 voltage of the raster luminance control unit as the beam current increases in the high voltage winding of the flyback transformer. A beam current limiter which controls the output to limit the beam current, and a microcomputer that outputs a control signal to the flyback transformer driving and deflection unit and outputs a G1 voltage adjustment signal to the raster luminance controller so as to correspond to an external operation command. Characterized in that configured.

Hereinafter, a preferred embodiment of the beam current limiting device of the monitor according to the present invention with reference to the accompanying drawings.

2 is a circuit diagram showing the configuration of the beam current limiting device of the monitor according to the present invention.

As shown in FIG. 2, the beam current limiting device of the monitor according to the present invention drives the FBT 22 to generate a high voltage, and drives the FBT 22 and the horizontal deflection yoke HDY according to a control signal. And a raster luminance controller 24 which controls the raster brightness by adjusting the G1 voltage of the CDT according to the deflection unit 21, the G1 voltage adjustment signal, and R according to an increase in the beam current flowing in the high voltage winding of the FBT 22. Abnormality of the high voltage output from the secondary winding of the FBT 22 and the beam current limiter 23 which controls the beam current by controlling the G / B output voltage or the G1 voltage adjustment output of the raster luminance controller 24. The high voltage detector 25 detects a voltage and outputs a detection signal, and controls the FBT driving and deflection unit 21 by detecting a voltage abnormality of the FBT 22 according to the detection signal output from the high voltage detector 25. And a microcomputer 2 for outputting a G1 voltage adjustment signal to the raster luminance control unit 24. 6) is configured to include.

In this case, the FBT driving and deflection unit 21 includes a variable resistor VR11 for adjusting the high voltage of the FBT 22 output, a transistor Q11 for generating the B + high voltage for driving the FBT 22, and a horizontal deflection yoke HDY. Generates a square wave corresponding to the duty ratio set by the variable resistor VR11 according to the control signal of the microcomputer 26 and the transistor Q12 for driving the output signal to the transistor Q11 and generates a horizontal driving pulse. And a synchronization signal processor 31 for outputting to the transistor Q12.

The beam current limiter 23 drops the R / G / B output voltage level so as to be proportional to the voltage drop across the resistor R14 by the beam current Ib flowing in the high voltage winding of the FBT 22, thereby reducing the beam current. A first transistor Q16 for limiting, a first resistor R14 for setting a beam current limit value, and both ends of the first resistor R14 are connected to a base and an emitter, and power is applied to the emitter. A second transistor Q17 that is turned on / off according to a voltage induced across the first resistor R14, and a second resistor R16 connected between the emitter of the second transistor Q17 and the first resistor R14. ) And a third resistor (R15) connected to the second transistor (Q17) collector and the G1 voltage adjustment signal input terminal of the raster luminance control unit 24 to include a G1 voltage drop width setting unit for setting a G1 voltage drop width. It is configured by.

In this case, the first resistor R14 is set such that 'V _EB ' of the second transistor Q17 is 0.7 V and the beam current to be limited is 1 mA, such that 'V _EB ' = 1 mA × 'R14'. The resistors R16 and R15 are set to minimum values in order to increase the beam current suppression amount.

Then, the raster luminance control unit 24 amplifies the negative voltage V12 output from the secondary winding of the FBT 22 according to the G1 voltage adjustment signal output from the microcomputer 26 and supplies it to the G1 electrode of the CDT. It comprises three transistors Q14, Q15 and Q18 that make up the amplifier.

The high voltage detection unit 25 divides the voltage divided by the voltage dividing resistors R12 and R13 for dividing the voltage V11 output from the secondary winding of the FBT 22 and the voltage dividing resistors R12 and R13. When the voltage level is above a certain level, the transistor Q13 is turned on to output a high voltage detection signal having a 'low' level to the microcomputer 26.

The beam current limiting operation of the present invention configured as described above will be described.

First, when the monitor power is 'on', the microcomputer 26 outputs a control signal to the FBT driving and deflection unit 21 and outputs a G1 voltage adjustment signal to the raster luminance control unit 24.

According to the control signal of the microcomputer 26, the synchronization signal processing unit 31 of the FBT driving and deflection unit 21 generates a square wave corresponding to the duty ratio set by the variable resistor VR11 to generate the transistor Q11. And a horizontal driving pulse is generated and output to the transistor Q12.

Subsequently, the transistor Q11 supplies the B + voltage to the FBT 22 and the transistor Q12 supplies the horizontal driving pulse to the horizontal deflection yoke HDY, so that the FBT 22 outputs a high voltage and a negative voltage V12. .

The raster luminance control unit 24 amplifies the negative voltage V12 output from the FBT 22 according to the G1 voltage adjustment signal of the microcomputer 26 and applies it to the G1 electrode of the CDT.

At this time, when the high voltage of the FBT 22 does not increase in the normal operation state of the monitor and only the beam current Ib increases, a voltage drop of 'Ib × R14' is generated by the resistance R14 of the beam current limiter 23. do.

Subsequently, the voltage drop decreases the collector voltage level of the first transistor Q16 of the beam current limiter 23, thereby reducing the output gain of the image preamplifier and eventually reducing the R / G / B output voltage level to thereby reduce the beam current. Will be limited.

On the other hand, when the IRLC test according to the FDA standard by varying the variable resistor (VR11) to increase the high voltage level so that the high voltage limiting operation is not performed, the beam current (Ib) increases in proportion to it.

At this time, when the beam current exceeds the current limit value set by the first resistor R14 of the beam current limiting unit 23, for example, 1 mA, the voltage drop by the first resistor R14 becomes' _Beyond V _EB ', the second transistor Q17 is turned on.

Subsequently, the I _C current flowing as the second transistor Q17 is turned on lowers the G1 output voltage of the transistors Q14, Q15 and Q18 constituting the Darlington amplifier of the raster luminance control unit 24, so that the beam current Limited at levels slightly above 1mA.

And, by adjusting the FBT winding, 'V12' can be set low enough so that the G1 voltage can drop below the FDA's IRLC standard.

In addition, since the beam current is limited in the above-described manner, the sealing process of the variable resistors VR11 and VR12 is unnecessary.

The beam current limiting device of the monitor according to the present invention has the following effects.

First, the anomalous increase in beam current is perfectly constrained by limiting the beam current through the G1 voltage drop, which detects an anomalous increase in beam current and provides the source of the beam current increase.

Second, the beam current is limited through the G1 voltage drop, which eliminates the need for a variable resistor sealing operation for high voltage adjustment and screen voltage adjustment, which simplifies the production process and shortens the time, thereby improving production efficiency.

Claims (3)

In the monitor provided with a cathode ray tube, A flyback transformer for generating a high voltage for driving the cathode ray tube, A flyback transformer driving and deflecting unit for driving the flyback transformer and the horizontal deflection yoke according to a control signal; Raster brightness control unit for controlling the raster brightness by adjusting the G1 voltage of the cathode ray tube according to the G1 voltage adjustment signal, A beam current limiter configured to limit the beam current by controlling the G1 voltage regulation output of the raster luminance controller in accordance with an increase in the beam current flowing through the high voltage winding of the flyback transformer; And a microcomputer that outputs a control signal to the flyback transformer driving and deflection unit and outputs a G1 voltage adjustment signal to the raster luminance control unit so as to correspond to an external operation command. According to claim 1, The beam current limiter may include a first resistor for setting the beam current limit value, A transistor connected across the first resistor to a base and an emitter and powered on the emitter, the transistor being on / off in accordance with a voltage induced across the first resistor, A second resistor connected between the transistor emitter and the first resistor and a third resistor connected to the transistor collector and the G1 voltage adjustment signal terminal of the raster luminance control unit to set a G1 voltage drop width; Beam current limiting device of the monitor, characterized in that it comprises a setting unit. The method of claim 2, And a G1 voltage drop width increases as the second and third resistance values are decreased.