KR200145467Y1 - Power stabilization circuit using transistor in a monitor - Google Patents

Abstract

The present invention relates to a power supply stabilization circuit for stabilizing the high output voltage provided by the monitor power supply circuit using a transistor.

The circuit of the present invention converts the current flowing on the photodiode side into an optical signal, and converts the optical signal back into an electrical signal to isolate the photodiode side and the phototransistor side and transmit a feedback signal. Photo couplers 320a and 320b to be used; An output voltage detector 310 for causing a current proportional to the magnitude of the output voltage to flow to the photodiode side of the photocoupler; A transistor Q32 for setting the feedback current small by flowing a base current to the photodiode side of the photocoupler; A zener diode (ZD31, ZD32, ZD33) connected to the output voltage detector to protect the output voltage detector; And a transistor Q31 for transferring a change in current corresponding to a change in output voltage through the zener diode to the output voltage detector.

Therefore, the voltage stabilization circuit according to the present invention can obtain a high output voltage for the same winding ratio by setting a small amount of current flowing through the photocoupler using a transistor, it is effective to protect the output voltage detector using a zener diode. .

Description

Voltage stabilization circuit using transistor in monitor

The present invention relates to a power supply circuit of a monitor, and more particularly to a power supply stabilization circuit for stabilizing the voltage provided by the monitor power supply circuit using a transistor.

Generally, the power system of the monitor receives AC power, rectifies and induces secondary power through the transformer to supply the various powers required by the circuit, and inputs the DC voltage provided from the SMPS power supply to receive the B + voltage to the FBT. DC-DC converter for providing a high voltage, screen voltage, control grid voltage and the like required for the CRT.

Fig. 1 is a circuit diagram showing an SMPS power supply of a monitor, which is a line filter (L1, L2), XY capacitors (C1, C2, C3), diode bridge 100, inrush current prevention resistor (R2), power supply. The control integrated circuit 110, the switching transistor Q1, the transformer 120, the diode D2, the smoothing capacitor C6, the photocouplers 140a and 140b, the output voltage detector 130, and the like.

That is, in FIG. 1, the DC voltage rectified by the diode bridge 100 is applied to the primary side of the transformer 120, and the DC voltage accumulates energy in the primary winding during the turn-on period of the switching transistor Q1. Energy is transferred to the secondary winding during the turn-off period of the switching transistor Q1, and each secondary winding is induced with the desired voltage by the turns ratio with the primary winding, and the diode D2 and the smoothing capacitor C6 Outputs a predetermined DC voltage.

When the DC voltage output from the secondary side of the transformer 120 is a relatively low voltage such as 5V, 12V, or 24V, a regulator integrated circuit (IC), which is readily available on the market, such as 7805, 7912, and 7824, may be used. A stable voltage is provided to each circuit element of the monitor.

On the other hand, the change in the output voltage in the monitor power supply circuit is detected by the output voltage detector 130, the detected voltage is represented as a change in the current flowing through the photocoupler (140a, 140b) connected to the output voltage detector (130) This change in current will change the amount of light emitted from the photodiode in the photocoupler. The change in the amount of light in the photocoupler is represented by the change of the collector current in the photo transistor, and the change of the current is connected to the feedback input terminal of the power control integrated circuit to stabilize the output voltage.

That is, in the conventional SMPS, the change of the output voltage Vout is fed back into the power control integrated circuit device 110 through the photocouplers 140a and 140b. As a result, the power control IC 110 receives the duty ratio of the PWM pulse. By varying, stabilize the output voltage constantly.

However, the amount of current flowing to the photodiode side of the photocoupler in the SMPS power circuit is determined by the values of the resistors R4 and R5 connected to the output voltage detector 130. Therefore, in order to obtain a high voltage output on the secondary side, the amount of current flowing through the photocoupler 140a is made very small to increase the duty ratio of the PWM signal, thereby increasing the turn-on time of the switching transistor Q1. If the values of R4 and R5 are too large, the rated voltage of the output voltage detector 130 may be exceeded, and even if the rated voltage is not reached, very large heat is generated in the output voltage detector, thereby reducing the life of the IC. There is a problem that can not shorten and obtain the desired high pressure.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, and an object thereof is to provide a power stabilization circuit using a transistor for stabilizing a high voltage output of a monitor power supply circuit.

The apparatus of the present invention for achieving the above object is, after receiving the AC power and rectified and applied to the primary side of the transformer connected to the switching transistor, by switching of the switching transistor in accordance with the output of the power control integrated circuit device In the power supply of the monitor to induce the primary side voltage to the secondary side to rectify and supply power to the load, converting the current flowing from the photodiode side to an optical signal, and converts the optical signal on the photo transistor Photocouplers 320a and 320b for converting back into electrical signals to isolate the photodiode side and the phototransistor side and transmitting a feedback signal; An output voltage detector 310 for causing a current proportional to the magnitude of the output voltage to flow to the photodiode side of the photocoupler; A transistor (Q32) for setting the feedback current small by allowing a base current to flow on the photodiode side of the photocoupler; A zener diode (ZD31, ZD32, ZD33) connected to the output voltage detector to protect the output voltage detector; And a transistor Q31 for transmitting a change in current corresponding to a change in output voltage through the zener diode to the output voltage detector.

1 is a circuit diagram showing a power supply circuit of a general monitor;

FIG. 2 is an equivalent circuit diagram of the output voltage detector shown in FIG. 1;

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

* Explanation of symbols for main parts of the drawings

100: diode bridge 110: power supply control IC

120: transformer 130, 310: output voltage detector

140a, 140b, 320a, 320b: photocoupler 300: power stabilizer

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

2 is an equivalent circuit diagram of an output voltage detector used in a monitor power supply circuit, and FIG. 3 is a circuit diagram showing a monitor power supply circuit including a power stabilization circuit according to the present invention.

As shown in FIG. 2, the output voltage detector 130 is equivalently represented by a transistor Q1 to which resistors R21, R22, R23 and a zener diode ZD20 are connected. Is the sensing terminal for the terminal, ② terminal is the collector terminal for connecting the photo coupler, and ③ terminal is the ground terminal.

This output voltage detector causes a very large collector current to flow through terminal ② in proportion to the magnitude of the current flowing through the terminal. Such an output voltage detector is widely used to monitor the output voltage at the output voltage terminal of the SMPS as shown in FIGS. 1 and 3.

That is, in FIGS. 1 and 3, when the output voltage Vout1 is increased to increase the current flowing through the ① terminal, more current flows to the photocoupler 140a connected to the ② terminal. Since the current Vfb fed back to the control chip 110 is increased, the power supply control chip 110 generates a PWM pulse having a small duty ratio to drive the switching transistor Q1, so that the voltage induced to the secondary side is relatively It becomes small and the output voltage Vout1 becomes low.

On the contrary, when the output voltage is lowered and the current flowing through the ① terminal decreases, the current flowing through the photocoupler 140a connected to the ② terminal is further reduced. Accordingly, the current Vfb fed back to the power control chip 110 is reduced. ), The power supply control chip 110 generates a PWM pulse having a large duty ratio to drive the switching transistor Q1. Accordingly, the voltage induced to the secondary side is relatively increased so that the output voltage Vout1 increases. Will be higher.

And, the rated voltage of such an output voltage detector is about 150V. When the output voltage is higher than this, the output voltage detector may burn out.

Therefore, the voltage stabilization circuit according to the present invention has an effect of increasing the rated voltage of the output voltage detector by connecting three zener diodes ZD31, ZD32, and ZD33 in series to the ① terminal of the output voltage detector, as shown in FIG. The emitter of transistor Q31 is connected to the zener diode ZD31 and the output voltage Vout1 divided by the resistors R321 and R32 is applied to the base of the transistor Q31. It is. Therefore, the emitter current of this transistor Q31 increases and decreases according to the magnitude of the output voltage Vout1, and this current flows to the terminal 1 of the output voltage detector.

The photodiode side of the photocoupler 140a is connected to terminal ② of the output voltage detector, and the emitter of the PNP transistor Q32 is connected to the photocoupler 140a, and the emitter of the transistor Q32 is The resistor R34 is connected to the output voltage Vout1, and the collector is connected to the ground through the resistor R36. At this time, the base of the transistor Q32 and the emitter are connected by the resistor R35. Therefore, since most of the current of the PNP transistor Q32 flows through the emitter and collector of the transistor Q32, and a small amount of base current flows through the photocoupler 320a, the feedback current is set small so that the high voltage The output of Vout1 can be obtained.

On the other hand, the power supply circuit of a typical monitor to which the present invention is applied, as shown in Figure 3, the line filter (L1, L2), XY capacitors (C1, C2, C3), diode bridge 100, inrush current protection resistor ( R2), the power supply control integrated circuit 100, the switching transistor Q1, the transformer 120, the diode D2, the smoothing capacitor C6, the voltage stabilization circuit 300, and the like.

Referring to FIG. 3, the line filters L1 and L2 and the X capacitor C1 remove noise and the like from a commercial AC power input through a line, and the Y capacitors C2 and C3 have the diode bridge 100 turned on. Bypassing internal noise to ground prevents the noise generated during on / off operation from going out through the line.

As described above, the AC power in which the noise is removed from the AC input circuit is rectified by the diode bridge 100 and flows through the primary winding of the transformer 120 through the inrush current preventing resistor R2 and the smoothing capacitor C4. At this time, the switching transistor Q1 is connected to the other side of the primary winding of the transformer and turned on and off according to the output of the power control integrated circuit (eg, the 3842 PWM control IC 110).

That is, the power control integrated circuit 110 receives the feedback signal Vfb through the photocoupler 140b and generates a PWM signal of a predetermined frequency whose duty ratio is variable according to the magnitude of the feedback signal, and the switching transistor Q1. Is turned on and off according to this PWM signal to flow or block the current input through the diode bridge to ground.

For example, when the switching transistor Q1 is turned on, a positive voltage is applied to the dot side of the primary winding of the transformer 120 and a current flows through the transistor Q1, and a voltage having the dot side in the + direction in the secondary winding. The induced voltage is applied to the diode D2 in the reverse direction to block the diode D2 and to accumulate energy in the primary winding.

Then, when the switching transistor Q1 is turned off, the primary side suddenly stops flowing current, thereby releasing the voltage in a direction (the dot side is-) to keep the current flowing, and also the dot side on the secondary side. This is induced and a forward voltage is applied to the diode D2. Therefore, on the secondary side, the output voltage Vout1 appears while charging the capacitor C6. Subsequently, when the switching transistor Q1 is turned on, as described above, the secondary diode D2 is cut off, so that the voltage of the capacitor C6 that has been charged up to the output side Vout1 appears.

As the current flows through the primary winding during the period in which the switching transistor Q1 is turned on, energy is accumulated in the primary winding, and when the switching transistor Q1 is turned off, energy is induced in the secondary winding by the primary and secondary winding ratios. The rectified voltage is represented as the secondary output DC voltage through the rectifying diode D2 and the smoothing capacitor C6. This method is called a flyback converter and it is easy to configure the output voltage in multiple because the secondary side configuration is simple.

On the other hand, the output voltage of such a power supply device is configured to stabilize the power supply control IC by controlling the PWM pulse width in response to the change of the output voltage detected by the output voltage detector. In order to obtain a high voltage, a high voltage can be obtained by deliberately reducing the amount of current flowing through the photocoupler transmitting the feedback signal.

That is, as shown in FIG. 3, the base current of the transistor Q32 flows through the photocoupler 320a so that the current of the photocoupler 320a is basically set small so that the output voltage is controlled by the power supply control IC 110. Then, the zener diodes ZD31, ZD32, and ZD33 are connected to the ① terminals of the output voltage detector 310 to protect the output voltage detector 310, and at the same time, the transistor Q31 of the transistor Q31 is changed in accordance with the change of the output voltage. When the emitter current changes, the current at the ① terminal of the output voltage detector is changed accordingly.

As described above, the voltage stabilization circuit according to the present invention can obtain a high output voltage for the same winding ratio by setting a small amount of current flowing through the photocoupler using a transistor, and protect the output voltage detector using a zener diode. It can be effective.

Claims (1)

After receiving and rectifying AC power, the switching transistor is applied to the primary side of the connected transformer, and the primary side voltage is induced to the secondary side by the switching of the switching transistor according to the output of the power control integrated circuit device, and then rectified. In the power supply of the monitor to supply power to the load, A photocoupler 320a for converting a current flowing from the photodiode side into an optical signal and converting the optical signal back into an electrical signal to isolate the photodiode side and the phototransistor side and to transmit a feedback signal. , 320b); An output voltage detector 310 for causing a current proportional to the magnitude of the output voltage to flow to the photodiode side of the photocoupler; A transistor (Q32) for setting the feedback current small by allowing a base current to flow on the photodiode side of the photocoupler; A zener diode (ZD31, ZD32, ZD33) connected to the output voltage detector to protect the output voltage detector; And A voltage stabilization circuit using a transistor in a monitor comprising a transistor (Q31) for transmitting a change in current corresponding to a change in output voltage through the zener diode to the output voltage detector.