KR100191247B1 - High voltage stabilization circuit - Google Patents

Abstract

The present invention relates to a high voltage stabilization circuit of a monitor, and according to the feedback voltage sensed from the FBT, the buck converter controls the B + voltage applied to the FBT by PWM control of the DC input, and thus is applied to the anode of the water pipe. A high voltage circuit of a monitor configured to stabilize a high voltage, the high voltage circuit comprising: a buffer (20) which detects a change in the ABL current from the FBT and amplifies it to a predetermined size; And a feedback voltage transfer unit 22 for transferring the output of the buffer to the input of the buck converter, thereby sensitively reacting to the fluctuation of the high voltage applied to the anode of the monitor receiving tube, thereby stabilizing the high voltage.

Description

Monitor's High Voltage Stabilization Circuit

1 is a conventional monitor high voltage stabilization circuit diagram.

2 is a circuit diagram showing a high voltage stabilization circuit of the monitor according to the present invention.

* Explanation of symbols for main parts of the drawings

10: FBT 12: feedback voltage detector

14: mute control unit 20: buffer

22: feedback voltage transmission unit 41: buck converter

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high voltage stabilization circuit of a monitor. In particular, a high voltage stabilization circuit of a monitor in which an output of an ABL detector for automatically adjusting luminance is input to a buck converter as a feedback voltage to stabilize a high voltage applied to an anode of a monitor receiving tube. It is about.

In general, the anode of the monitor tube is supplied with a high voltage of several tens of KV, and the high voltage supplied is a pulse obtained by using a rapid current change in the return period when a sawtooth current for horizontal deflection is obtained. It is generated by boosting the voltage. At this time, a voltage fluctuation occurs in the boosted high voltage, and when the high voltage with the voltage fluctuation is applied to the anode of the water pipe as it is, the horizontal and vertical screens change, so it is necessary to stabilize this high voltage.

In the conventional high voltage stabilization circuit, the high voltage applied to the anode of the water pipe is obtained by switching the voltage output from the buck converter in the return period for horizontal deflection at the horizontal output unit to boost the pulse generated at this time. At this time, since the voltage fluctuation may occur in the high voltage applied to the anode which is the water pipe, the high voltage is stabilized by installing a sensing circuit in the flyback transformer (hereinafter referred to as FBT) to reduce the voltage fluctuation.

That is, the conventional high voltage stabilization circuit is composed of the FBT 10, the feedback voltage detector 12, the buck converter 16, as shown in Figure 1, the feedback voltage detector 12 detects from the FBT (10) When the detected voltage is detected and output to the buck converter 16 through the resistor R7, the buck converter 16 controls the magnitude of the B + voltage by PWM control of the DC input, thereby inducing the secondary side of the FBT 10. The magnitude of the high voltage to be controlled was appropriately controlled. At this time, the FBT is provided with an ABL detection circuit for the Automatic Brightness Limit (ABL) function, and the feedback voltage input to the buck converter 16 is varied according to the mute function. Here, the mute function will be briefly described. When the mute signal 'low' is input from the microcomputer (not shown), the transistor Q1 is turned on so that the resistor R2 connected in parallel with the transistor Q1 is almost separated from the circuit. The feedback voltage input to the buck converter causes the voltage sensed from the FBT to be a voltage divided by the resistors R1 and R3 and R4.

On the contrary, if the microcomputer outputs a mute signal of 'high', the transistor Q1 is turned off and the feedback voltage input to the buck converter 16 is such that the voltage sensed from the FBT 10 is equal to the resistance R1. The voltage is divided by the resistors R2, R3, and R4. For example, if the detected voltage is 30V, the feedback voltage when the mute signal is 'low' is 30V x (R3 + R4) / (R1 + R3 + R4), and when the mute signal is 'high', 30V x ( Since R2 + R3 + R4) / (R1 + R2 + R3 + R4), the feedback voltage when the mute signal is 'high' is larger than when the feedback voltage is 'low'. Therefore, when the mute is applied, the buck converter 16 lowers the voltage applied to each part of the monitor by controlling the B + voltage low.

However, the conventional high voltage stabilization circuit has a problem that it is difficult to sufficiently stabilize the high voltage applied to the anode of the receiving tube because the fluctuation range of the detection voltage of the feedback voltage detection unit is small so that it does not react sensitively to the fluctuation of the high voltage.

Accordingly, the present invention has been made to solve the above problems, the object of the present invention is to provide a high voltage stabilization circuit of the monitor to be able to stabilize the high voltage by sensitively detecting the voltage change of the high voltage applied to the anode of the water pipe. have.

In order to achieve the above object, the present invention, according to the feedback voltage sensed from the FBT, the buck converter PWM control the DC input to control the B + voltage applied to the FBT, accordingly to apply to the anode of the water pipe A high voltage circuit of a monitor configured to stabilize a high voltage, comprising: a buffer for detecting a change in an ABL current from the FBT and amplifying a predetermined size; And a feedback voltage transfer means for transferring the output of the buffer to the input of the buck converter.

At this time, the feedback voltage transmitting means is composed of a first capacitor having a relatively large capacity and a second capacitor having a relatively small capacity so that the output of the fraud amplifying means is sensitively transmitted to the feedback input terminal of the buck converter through the second capacitor. It is configured to hold to a predetermined size by a capacitor.

Therefore, the high voltage variation detected through the ABL current is transmitted sensitively to the buck converter without affecting other circuits, and there is no need to adjust the parameters of the existing circuit.

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

As shown in FIG. 2, the high voltage stabilization circuit of the monitor according to the present invention includes an FBT 10, a feedback voltage detector 12, a buck converter 41, a mute unit 14, a buffer 20, and a feedback voltage. It is comprised by the transmission part 22.

In FIG. 2, the feedback voltage detector 12 is composed of a diode D10, a resistor R10, and a capacitor C10 to detect a change in high voltage from the FBT 10 and output the same to the buck converter 41. This voltage input to the buck converter 41 is the feedback voltage V _FB . As described above, the magnitude of the feedback voltage varies depending on the mute function. For example, when a mute signal 'low' is input from a microcomputer (not shown), the transistor Q1 of the mute unit 14 is turned on to the transistor Q1. The feedback voltage inputted to the buck converter 41 is such that the parallel connected resistors R2 are substantially separated from each other so that the voltage sensed from the FBT becomes a voltage divided by the resistors R1 and R3 and R4. On the contrary, if the microcomputer (not shown) outputs a mute signal of 'high', the transistor Q1 is turned off and the feedback voltage input to the buck converter 16 is such that the voltage sensed from the FBT 10 is the resistance R1 and the resistor. The voltage is divided by (R2, R3, R4).

At this time, the feedback voltage input to the buck converter 41 is more sensitively changed not only by the output of the feedback voltage detector 12 but also by the ABL current transmitted by the buffer 20 and the feedback voltage transmitter 22 according to the present invention. do.

That is, the buffer 20 is implemented as emitter follower circuits Q20, R90, and R100 that receive and buffer the ABL current for the ABL function from the FBT 10, and the variable resistor connected to the emitter of the transistor Q20. The output voltage can be adjusted by R90, and the feedback voltage transfer unit 22 is implemented as a capacitor C20 and C40 connected in series so that the output terminal of the emitter follower has a common connection point 2 of the capacitor C20 and C40. ) In this case, the first capacitor C40 connected to the ground has a relatively large capacity, and the second capacitor C20 connected to the feedback voltage terminal 1 has a relatively small capacity. For example, when the ratio of the capacity of the first capacitor C40 to the capacity of the second capacitor C20 is about 100: 1, the variation of the output of the emitter follower by the second capacitor C20 is sensitive to the feedback voltage stage. Although transmitted, the fluctuation of the first capacitor C40 is insensitive. In other words, as the output of the emitter follower changes, the voltage of the second capacitor C20 easily causes charge / discharge, but since the first capacitor C40 has a large capacity, the charge / discharge fluctuates smoothly. In this way, by combining the variation of the ABL current to the output terminal 1 of the existing feedback voltage detection unit using a capacitor, it is possible to sensitively detect the variation of the high voltage without affecting the existing circuit.

In addition, the mute unit 14 includes a transistor Q10 turned on and off in response to a mute signal input from the microcomputer, a resistor R20 and a bias resistor R50 connected in parallel to the transistor. As described above, the monitor is operated stably by forcibly lowering the B + voltage during initial power-on or mode change. The resistors R30 and R40 of the mute part are voltage division resistors, and in particular, the value of V _FB may be adjusted by adjusting the size of the resistor R40.

The buck converter 41 controls the B + voltage to a predetermined voltage by PWM controlling the DC input according to the feedback voltage. For example, when the B + voltage applied to the primary side of the FBT 10 becomes higher than the normal value, the buck converter 41 moves to the secondary side accordingly. The magnitude of the induced high voltage is also increased, and the feedback voltage V _FB which detects the variation of the high voltage on the FBT is also increased. The buck converter 41 compares the feedback voltage with an internal reference voltage (for example, about 2.5 V). When the feedback voltage is increased, the buck converter 41 adjusts the pulse width of the PWM to lower the B + voltage. On the contrary, when the B + voltage is lower than the normal value, the feedback voltage is lowered accordingly, so the buck converter 41 adjusts the pulse width of the PWM to increase the B + voltage.

As described above, the present invention senses the change in the high voltage to be applied to the anode of the water pipe by using the ABL current detector, so that it is sensitive to the change of the high voltage applied to the anode of the monitor water pipe, and thus stabilizes the high voltage. There is an effect that can be stabilized.

Claims (3)

According to the feedback voltage sensed from the FBT 10, the buck converter 41 controls the B + voltage applied to the FBT 10 by PWM controlling the DC input, thereby stabilizing a high voltage for applying to the anode of the water pipe. A high voltage circuit of a monitor, comprising: a buffer (20) for detecting a change in an ABL current from the FBT and amplifying the current to a predetermined size; And a feedback voltage transfer unit (22) for transferring the output of the buffer to the input of the buck converter. 2. The high voltage stabilization circuit of a monitor according to claim 1, wherein said buffer (20) is implemented by an emitter follower circuit. 2. The high voltage stabilization circuit of a monitor according to claim 1, wherein the voltage transfer means (22) includes a first capacitor (C40) having a relatively large capacitance and a second capacitor (C20) having a relatively small capacitance.