KR100191250B1 - Power stabilization circuit - Google Patents

Abstract

The present invention relates to a power supply stabilization circuit of a monitor, and the voltage V _FB1 fed back from the flyback transformer 240 depends on the feedback voltage V _{FB2 dropped} by the split resistors R1, R2, and R3. DC-DC converter 230 for outputting a predetermined B ⁺ voltage by PWM control the DC input voltage (Vin) is provided, and when the microcomputer 200 outputs a mute on signal is connected in parallel to the one divided resistor (R2) By turning off the switching transistor TR to increase the feedback voltage V _FB2 , the B ⁺ voltage output by the DC-DC converter 230 is lower than the normal B ⁺ voltage, and the microcomputer 200 mutes off. When the output signal of the switching transistor (TR) is turned on in the power supply stabilizing circuit of the feedback voltage (V _FB2), the writing is lowered cost so as to provide a B ⁺ voltage in the steady-state monitor, the microcomputer 200 and the switching transistor ( TR) is connected to the microcomputer 200 The current interrupting unit 210 is provided to prevent the feedback voltage V _FB2 from being changed by the output mute on / off signal, so that the current due to the mute signal voltage is reduced by the feedback input voltage of the DC-DC converter 230. This has the advantage of providing stable power to each part of the monitor without affecting it.

Description

Power Stabilization Circuit of Monitor

1 is a circuit diagram showing a power supply circuit of a conventional monitor.

(A) and (b) of FIG. 2 are waveform diagrams for explaining the power supply circuit of FIG.

3 is a circuit diagram showing a power supply stabilization circuit of a monitor according to the present invention.

(A) and (b) of FIG. 4 are waveform diagrams for explaining the power supply stabilization circuit of FIG.

* Explanation of symbols for main parts of the drawings

200: microcomputer 210: current breaker

220: voltage drop 230: DC-DC converter

240: flyback transformer 250: horizontal output unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply stabilization circuit of a monitor, and more particularly, to a power supply stabilization circuit of a monitor which prevents an output voltage of a power supply circuit from being unstable due to a mute signal output from a microcomputer when a power is turned on or a mode is changed. .

In general, when the monitor is powered on or the mode is switched to supply the necessary voltage to each part at the time, it causes an abnormality in the monitor circuit.

Therefore, a mute function should be provided so that the power circuit can operate normally after the power supply circuit is ready for operation (warm-up) when the monitor is powered on or when the mode is switched. The mute function is used for normal operation. It is the function to supply the ready voltage lower than the required voltage (normal voltage) first and then supply the normal voltage.

However, the power supply circuit of a conventional monitor having a mute function as described above has a problem that the current due to the mute signal voltage output from the microcomputer affects the feedback input voltage of the DC-DC converter, causing the power supply circuit to malfunction. .

1 is a circuit diagram showing a power supply circuit of a conventional monitor having the above problems, wherein the power supply circuit of the conventional monitor includes a microcomputer (100); Voltage drop unit 120; DC-DC converter 140; Fly back transformer 160; And a horizontal output unit 180.

Here, the voltage drop unit 120 is composed of a resistor (R1, R2, R4, R5, R6), a variable resistor (R3), a capacitor (C) and a PNP type switching transistor (TR), the flyback transformer The 160 may include an output terminal of the DC-DC converter 140, a primary side coil connected to the horizontal output unit 180, a secondary side coil connected to each part of the monitor, and an input terminal of the voltage drop unit 120.

Next, the operation of the power supply circuit of the conventional monitor configured as described above will be described with reference to FIGS. 1 and 2.

(A) of FIG. 2 is a waveform diagram of the mute signal output from the microcomputer 100, and (b) is a waveform diagram of the B ⁺ voltage output from the DC-DC converter 140. In (b) of FIG. The solid line represents the actual variation of the B ⁺ voltage output by the DC-DC converter 140, and the dotted line represents the variation of the desirable B ⁺ voltage. In addition, in Fig. 2B, a is an overshoot generated when the power is first turned on.

First, the DC-DC converter 140 of FIG. 1 outputs a stable B ⁺ voltage by appropriately controlling the pulse width modulation (PWM) of the input DC voltage V _IN according to the magnitude of the feedback voltage V _FB2 . In general, the mute function is to adjust the magnitude of the B ⁺ voltage by manipulating the magnitude of the feedback voltage (V _FB2 ) as necessary.

For example, when the B ⁺ voltage of the DC-DC converter 140 in the steady state is about 65 V, the DC-DC converter 140 is input to the DC-DC converter 140 when a sudden voltage change is required, such as when the power is turned on or when the mode is changed. By increasing the feedback voltage (V _FB2 ) to lower the B ⁺ voltage to about 45V to prevent excessive power supply circuit.

Referring to the operation of the monitor, since the mute function needs to be turned on when the power is turned on or when the mode is switched, the high signal from the microcomputer 100 passes through the resistor R5 to turn on the mute function. It is input to the base end of the) to turn off the switching transistor (TR).

When the switching transistor TR is turned off, the feedback voltage V _FB2 input to the DC-DC converter 140 is converted by the resistors R1, R2 and the variable resistor R3 from the voltage V _FB1 fed back from the flyback transformer 160. Dropped voltage Becomes At this time. Current due to the high signal from the microcomputer 100 flows along the I _H2 path shown in FIG.

On the other hand, when a low signal is output from the microcomputer 100 such that the power supply circuit starts normal operation again after the predetermined stabilization period elapses, that is, the mute function is turned off, the switching transistor TR is turned on and the DC-DC converter 140 is turned on. The feedback voltage V _FB2 inputted to the voltage _VFB2 fed back from the flyback transformer 160 is the voltage _dropped by the resistors R1 and R3. Becomes At this time, the path of the current flowing to the microcomputer 100 is I _L2 , I _L3 as shown in FIG. 1.

However, the input voltage of the DC-DC converter 140 due to the current I _H2 generated when the mute signal is high. Becomes larger, and accordingly, the B ⁺ voltage of the DC-DC converter 140 becomes smaller.

For example, as shown in (b) of FIG. 2, the output B ⁺ voltage of the DC-DC converter 140 is about 35V, which is lower than 45V, which is the B ⁺ voltage without the current I _H2 , so that the mute function is turned off when the DC-DC converter 140 of the B ⁺ voltage is normally higher again at about 65V claim severe overshoot to 2 degrees (b) the so the rise of the B ⁺ voltage becomes larger, as B ⁺ voltage change shown in ( Over Shoot (b) is generated to deteriorate the operating characteristics of a circuit device such as a switching transistor (not shown) of the horizontal output unit 180 and even break the circuit device.

Accordingly, the present invention has been made to solve the above problems, and stable B ⁺ power to each part of the monitor by preventing the current by the mute signal voltage output from the microcomputer does not affect the input voltage of the DC-DC converter. Its purpose is to provide a power supply stabilization circuit for the monitor that supplies it.

The power supply stabilization circuit of the monitor of the present invention for achieving the above object, PWM control the DC input voltage according to the feedback voltage dropped by the split resistors voltage from the flyback transformer to a predetermined B ⁺ voltage A DC-DC converter is provided, and when the microcomputer outputs a mute on signal, the switching transistor connected in parallel to the one division resistor is turned off to increase the feedback voltage to increase the B ⁺ voltage output by the DC-DC converter. In a power supply stabilization circuit of a monitor configured to provide a steady state B ⁺ voltage because the switching transistor is turned on when the microcomputer lowers the B ⁺ voltage and the microcomputer outputs a mute-off signal, thereby lowering the feedback voltage. Connected between the transistors and the currents according to the mute on / off signal outputted by the microcomputer. It characterized in that the current blocking means for preventing that the feedback voltage change equipped.

Therefore, the power supply circuit of the monitor configured as described above is stable at each part of the monitor by preventing the current caused by the mute signal voltage output from the microcomputer from affecting the feedback input voltage of the DC-DC converter when the power is turned on or the mode is switched. Power can be supplied.

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

3 is a circuit diagram illustrating a power supply stabilization circuit of a monitor according to the present invention, wherein the power stabilization circuit according to the present invention includes a microcomputer 200; A current blocking unit 210 and a voltage drop unit 220; DC-DC converter 230; Fly back transformer 240; And a horizontal output unit 250.

Here, the current blocking unit 210 is a cathode of the diode (D) and the capacitor (C) is commonly connected to the microcomputer 200, the anode of the diode (D) is connected to the voltage drop unit 220. The other side of the capacitor (C) has a structure connected to the ground.

The voltage drop unit 220 includes a resistor R1 connected in series with an input terminal of the capacitor C, the resistor R2, the emitter terminal of the PNP type switching transistor TR, the resistor R4, and the resistor R6. It is connected in parallel with the input terminal of the DC-DC converter 230 via the. In addition, the voltage drop unit 220 has the variable resistor R3 and the collector terminal of the switching transistor TR connected in parallel to the other side of the resistor R2, and the other side of the variable resistor R3 is grounded. The base terminal of the switching transistor TR has a structure in which a resistor R4 and a diode D of the current blocking unit 210 are connected in common.

In addition, the flyback transformer 240 is connected to an output terminal of the DC-DC converter 230 and a primary coil connected to the horizontal output unit 250, and to an input terminal of each part of the monitor and the voltage drop unit 220. It consists of secondary side coils.

Next, specific circuit operations of the embodiment of the present invention will be described with reference to FIGS. 3 and 4 (a) and (b).

Here, (a) of FIG. 4 is a mute signal output from the microcomputer 200, and (b) is a voltage waveform diagram of B ⁺ , which is an output voltage of the DC-DC converter 230.

First, the mute function is divided into on and off when the operation according to the present invention is easy to understand.

1.When the mute function is on (when the power is on or when the mode is switched)

When the mute function is turned on, such as when the power is turned on or at the time of mode conversion, the fourth switch is made to increase the feedback voltage V _FB2 by turning off the switching transistor TR connected in parallel to the split resistors R1, R2, and R3. As shown in FIG. 1A, the microcomputer 200 outputs a high signal.

This high signal voltage charges the capacitor C of the current blocking unit 210 according to the present invention, and applies a reverse bias to the diode D. Therefore, the diode D is turned off to cut off the current caused by the high signal of the microcomputer 200, but the high signal voltage causes the reverse bias to be applied to the base of the switching transistor TR so that the switching transistor TR is turned off. do.

As described above, when the switching transistor TR is turned off, a voltage drop is generated including the split resistors R1, R2, and R3 connected in parallel to the switching transistor TR as described above. Input feedback voltage is Becomes

However, in the related art, the current due to the high signal output from the microcomputer 200 flows further through the split resistors R2 and R3, so that the actual feedback voltage is higher than the designed feedback voltage, which is shown in FIG. As described above, the B ⁺ voltage at the time of muting output by the DC-DC converter 230 is 35V, which is lower than the designed 45V. However, in the present invention, the diode D of the current cut-off unit 210 receives the current by the mute on signal. By blocking, the actual B ⁺ voltage is maintained at about 45V, as shown in Figure 4 (b).

2. When the mute function is off (in normal operation)

After a certain stabilization period, the mute function should be turned off to supply a normal B ⁺ voltage. When the microcomputer 200 outputs a low signal to turn off the mute function, the capacitor C of the current blocking unit 210 is turned off. Is discharged to the microcomputer 200 through the resistor R5 and a forward bias is applied to the diode D of the current blocking unit 210 so that the diode D is turned on.

Accordingly, the feedback voltage input to the DC-DC converter 230 when the switching transistor TR connected in parallel to the split resistors R1 and R3 is turned on. Becomes

At this time, looking at the flow of current, most of the current (I _L1 ) due to the voltage dropped after being fed back from the flyback transformer 240 to the ground through the resistor R1, the switching transistor (TR), and the resistor (R3). The portion I _L2 flows to the microcomputer 100 through the diode D and the resistor R5.

As such, when the mute function is turned off, the feedback voltage V _FB2 input to the DC-DC converter 230 is lower than when the mute function is turned on, so the B ⁺ voltage output by the DC-DC converter 230 is shown in FIG. As shown in (b), the voltage is increased to about 65V to supply the B ⁺ voltage at the steady state.

As described above, according to the present invention, when the power supply is turned on or the mode is switched, the switching transistor TR is turned off by the mute on signal, so that the feedback voltage V _FB2 input to the DC-DC converter 230 is increased. -The DC converter 230 outputs a lower B ⁺ voltage in the normal state, and after a certain stabilization period, the switching transistor TR is turned on by the mute off signal and is input to the DC-DC converter 230. Since V _FB2 is lowered, the DC-DC converter 230 outputs the B ⁺ voltage in the normal state.

In this case, according to the present invention, the current blocking unit 210 added between the microcomputer 200 and the switching transistor TR blocks the current flow due to the mute signal, thereby satisfying the feedback voltage V _FB2 with the required design value. Accordingly, since the DC-DC converter 230 outputs a stable B ⁺ voltage, it is possible to prevent deterioration or breakage of operating characteristics of the circuit element due to overshoot during B ⁺ voltage fluctuation.

Claims (2)

The voltage V _FB1 fed back from the flyback transformer 240 is PWM-controlled by the DC input voltage Vin according to the feedback voltage V _{FB2 dropped} by the split resistors R1, R2 and R3. A DC-DC converter 230 for outputting a ⁺ voltage is provided, and when the microcomputer 200 outputs a mute on signal, the switching transistor TR connected in parallel to the one division resistor R2 is turned off, so that the feedback voltage V _{By increasing the FB2} ), the B ⁺ voltage output by the DC-DC converter 230 is lower than the normal B ⁺ voltage, and when the microcomputer 200 outputs a mute-off signal, the switching transistor TR is turned on. In the power supply stabilization circuit of the monitor to provide a steady state B ⁺ voltage by _reducing the feedback voltage V _FB2 , the microcomputer 200 is connected between the microcomputer 200 and the switching transistor TR. The feedback voltage (V _FB2) by a mute on / off signal Power supply stabilization circuit of the monitor, characterized in that provided with a current blocking unit 210 to prevent the fluctuation. The method of claim 1, wherein the current blocking means 210 is a diode (D) and a capacitor (C) is connected in series between the base and the ground of the switching transistor (TR), the diode (D) and the capacitor (C) The microcomputer 200 for outputting the mute signal is connected to a common connection point of the power supply stabilization circuit of the monitor.