KR20000013803U - Monitor overcurrent protection multi-level control circuit - Google Patents

Abstract

The purpose of the present invention is to reduce the brightness of the video signal step by step in order to alleviate the damage the monitor receives when the brightness level of the monitor increases and the beam current flows excessively. To provide a monitor overcurrent protection multi-stage control circuit to block the horizontal oscillation of the.

The present invention for achieving the above object is the first transistor 19, which is turned on by the off operation of the zener diode 18 when the beam current of the FBT (13) rises, and the collector output voltage of the first transistor (19) OCP 20 for detecting an overcurrent state, a horizontal oscillation IC 21 for blocking the horizontal oscillation output by the sense output of the OCP 20, the input voltage of the zener diode 18 and the output of the OCP 20 A second transistor 28 that amplifies the voltage difference between the voltages, a third transistor 35 that receives the output of the second transistor through the coupling capacitor 30 and adjusts and amplifies the DC level, and the third transistor Bias control and a secondary amplification circuit 37 for regulating the brightness control signal applied to the CRT 38 with a DC leveled output.

The present invention reduces the luminance value in proportion to the increase value when the monitor current increases, so that the impact of the monitor circuit due to the sudden operation of the overcurrent protection circuit at the threshold value can be prevented.

Description

Monitor overcurrent protection multi-level control circuit

The present invention relates to an overcurrent protection circuit that cuts off the beam current supplied to the monitor when the brightness level of the monitor increases and the beam current excessively flows. In particular, the overcurrent protection circuit suddenly supplies the monitor current at an arbitrary threshold. In order to alleviate the damage that the monitor receives when the power is cut off, if there is an increase in the luminance current in advance, the brightness of the video signal is lowered in proportion to it, and when a certain level is reached, the overcurrent protection circuit operates to the monitor. The present invention relates to an over-current protection multi-stage control circuit of a monitor that protects the monitor from damage caused by sudden over-current blocking by causing a horizontal oscillation that controls the current supply to be cut off.

The CRT of the monitor changes the brightness of the screen according to the intensity of the beam current output from the FBT. If the beam current is large, the monitor screen is brighter, and if the beam current is small, the screen is dark.

However, when the beam current that determines the brightness of the monitor screen exceeds a certain level, the OCP (Over Current Protection Circuit) operates to block the horizontal oscillation output to protect the circuit. The current output is cut off and the monitor enters overcurrent protection.

1 is a configuration diagram of a conventional monitor overcurrent protection circuit.

As referred to herein, the switching current is connected to the input coil of the FBT 13 according to the switching operation of the horizontal transistor 11 according to the horizontal control pulse input, and induced and output to the output coil of the FBT 13. The high voltage is connected to be applied to the anode of the CRT.

In addition, the high voltage output of the FBT 13 is divided by the focus resistor 14 and the screen resistor 15 so as to be applied to the focus control voltage and the screen control voltage, respectively.

The luminance current output of the FBT 13 is smoothed by the capacitor 17 and passed through the voltage divider resistor 16, and then connected to the base bias of the first transistor 19 through the zener diode 18. The B ⁺ voltage of 12V through the transistor 19 is connected to the OCP 20 as an overcurrent generating signal through a resistor and a capacitor.

The monitor overcurrent protection output of the OCP 20 is connected to the X-ray protector of the horizontal oscillation IC 21 and connected to the X-ray protector of the horizontal oscillation IC 21. When the overcurrent protection signal is input, the output terminal (OSC OUT) is connected to the horizontal oscillation output is configured to stop.

Referring to the operation of the conventional monitor overcurrent protection circuit configured as described above are as follows.

First, when a high voltage is generated at the output coil of the FBT 13 according to the operation of the horizontal output transistor 11, the high voltage is applied to the anode terminal, and the divided voltage-adjusted focus voltage, the screen voltage, and the brightness control beam current are respectively the focus circuit and It is applied to the screen circuit and the luminance circuit.

At this time, when the beam current supplied to the luminance circuit increases, that is, when the brightness of the monitor becomes bright, the voltage obtained from the voltage dividing resistor 16 decreases. When the voltage applied to the zener diode 18 does not exceed the set zener voltage, which is its conduction voltage, due to such a decrease in voltage, the base potential of the first transistor 19 falls from the high to the ground potential.

Accordingly, since the first transistor 19 is turned on, a voltage of 12 V due to the conduction of the first transistor 19 is input to the OCP 20. Since the OCP 20 recognizes the monitor overcurrent and provides the control signal for the protection circuit operation to the horizontal oscillation IC 21, the horizontal oscillation output is stopped in the horizontal oscillation IC 21, thereby increasing the excessive luminance current. To protect the monitor from deterioration.

However, in the conventional circuit as described above, when an excessive luminance current is generated, the overcurrent protection circuit suddenly operates at an arbitrary threshold, thereby interrupting the monitor current supply, so that the monitor circuit may be damaged by the shock.

The purpose of the present invention is to reduce the brightness of the video signal step by step in order to alleviate the damage the monitor receives when the brightness level of the monitor increases and the beam current flows excessively. It is to provide an over-current protection multi-stage control circuit of a monitor that can minimize the damage of the monitor caused by sudden protection circuit operation of the monitor circuit by blocking the horizontal oscillation of

1 is a configuration diagram of a conventional monitor overcurrent protection control circuit.

2 is a block diagram of a multi-stage control circuit in monitor overcurrent protection according to the present invention.

※ Explanation of symbols about main part of drawing ※

11: horizontal transistor 13: FBT (flyback transformer)

14: focus resistance 15: screen resistance

16,22,23,24,25,27,29,31,32,33,34: resistance

17,26,30: Capacitor 18: Zener Diode

19, 28, 35: transistor 20: OCP (over current protection circuit)

21: horizontal oscillation circuit 36: video signal preamplification circuit

37: bias control and secondary amplifier circuit

38: CRT

In order to achieve the above object, the present invention provides a first transistor that is turned on by the off operation of the zener diode when the beam current of the FBT rises, an OCP that senses an overcurrent state using the collector output voltage of the first transistor, and the OCP. A horizontal oscillation IC that cuts off the horizontal oscillation output with a sensing output of the second oscillator, a second transistor that amplifies the difference voltage between the input voltage of the zener diode and the output voltage of the OCP, and an output of the second transistor through a coupling capacitor. And a third transistor for controlling and amplifying the DC level, and a bias control and a secondary amplifier circuit for adjusting the brightness control signal applied to the CRT with the DC leveled output of the third transistor.

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

2 is a block diagram of a control circuit of the present invention. As referred to herein, the switching current is connected to the input coil of the FBT 13 according to the switching operation of the horizontal transistor 11 according to the horizontal control pulse input, and induced and output to the output coil of the FBT 13. The high voltage is connected to be applied to the anode of the CRT.

In addition, the high voltage output of the FBT 13 is divided by the focus resistor 14 and the screen resistor 15 so as to be applied to the focus control voltage and the screen control voltage, respectively.

The luminance current output of the FBT 13 is smoothed by the capacitor 17 and passed through the voltage divider resistor 16, and then connected to the base bias of the first transistor 19 through the zener diode 18. The B ⁺ voltage of 12V through the transistor 19 is connected to the OCP 20 as an overcurrent generating signal through a resistor and a capacitor.

The monitor overcurrent protection output of the OCP 20 is connected to the X-ray protector of the horizontal oscillation IC 21 and connected to the X-ray protector of the horizontal oscillation IC 21. When the overcurrent protection signal is input, the output terminal (OSC OUT) is connected to the horizontal oscillation output is configured to stop.

In addition, the input terminal voltage of the zener diode 18 and the output terminal voltage of the OCP 20 are drawn to the resistors 22 and 23, respectively, and the difference voltage component is passed through the resistors 24 and 25 and the capacitor 26 to the second transistor. And to be applied at a base bias voltage of (28).

The amplification of the second transistor 28 causes the Vcc voltage level to appear across the emitter resistor 29 through the collector resistor 27. The signal voltage is passed through the coupling capacitor 30 to control the DC level. 31-34) to be applied to the base of the third transistor (35).

The signal voltage appearing at the emitter output terminal of the third transistor 35 is connected to the bias control and the secondary amplifier circuit 37 so as to be applied as a monitor luminance current control signal.

Here, the diode 12 is for damping, and the video signal preamplification circuit 36 is a circuit for ultra-amplifying an RGB attraction signal.

Referring to the operation of the present invention configured as described above are as follows.

First, when a high voltage is generated at the output coil of the FBT 13 according to the operation of the horizontal output transistor 11, the high voltage is applied to the anode terminal, and the divided voltage-adjusted focus voltage, the screen voltage, and the brightness control beam current are respectively the focus circuit and It is applied to the screen circuit and the luminance circuit.

At this time, when the beam current supplied to the luminance circuit increases, that is, when the brightness of the monitor becomes bright, the voltage obtained from the voltage dividing resistor 16 decreases. When the voltage applied to the zener diode 18 does not exceed the set zener voltage, which is its conduction voltage, due to such a decrease in voltage, the base potential of the first transistor 19 falls from the high to the ground potential.

Accordingly, since the first transistor 19 is turned on, a voltage of 12 V due to the conduction of the first transistor 19 is input to the OCP 20. Since the OCP 20 recognizes the monitor overcurrent and provides the control signal for the protection circuit operation to the horizontal oscillation IC 21, the horizontal oscillation output is stopped in the horizontal oscillation IC 21, thereby increasing the excessive luminance current. To protect the monitor from deterioration.

On the other hand, it is understood that the beam current is gradually increased prior to the above operation by determining the voltage difference between the input side voltage of the zener diode 18 and the OCP 20. The increase and decrease of the voltage difference is amplified by the second transistor 28 and then input to the third transistor 35 through the coupling capacitor 30.

The third transistor 35 converts and outputs an input signal to a DC level, and the DC level output proportionally proportions the luminance value of the bias control and the secondary amplification circuit 37 to determine the brightness of the CRT 38. Will be lowered.

That is, the brightness of the bias control and the secondary amplification circuit 37 to the CRT 38 is controlled by the third transistor output that adjusts the DC level as the input voltage of the zener diode 18 and the difference voltage of the OCP 20 increase. By lowering the adjustment value, it is possible to minimize the shock received by the monitor when the horizontal output is finally blocked due to excessive beam current by the OCP (20).

As described above, the present invention reduces the brightness of the video signal step by step in proportion to the ice current increase when the brightness level of the monitor increases and the beam current excessively flows. Even if the supply is interrupted, there is a unique effect that can minimize the impact the monitor receives.

Claims (1)

The first transistor 19 is turned on when the output voltage drops below the zener voltage of the zener diode 18 due to the rise of the beam current of the FBT 13, and the overcurrent state is caused by the collector output voltage of the first transistor 19. In the over-current protection circuit comprising an OCP (20) for detecting a; and a horizontal oscillation IC (21) for blocking the horizontal oscillation output by the overcurrent sensing output of the OCP (20), the input voltage of the zener diode (18) A second transistor 28 for voltage-amplifying the voltage difference between the output voltage of the OCP 20 and the third transistor for controlling and amplifying the DC level by inputting the signal voltage output of the second transistor through the coupling capacitor 30. Over-current protection of the monitor, characterized in that it comprises a transistor 35 and a secondary amplification circuit 37 for regulating the brightness control signal applied to the CRT 38 with the DC leveled output of the third transistor. Multi-level control circuit.