KR920006763Y1 - Circuit for supplying automatic voltage - Google Patents

Abstract

No content.

Description

Automatic voltage supply circuit

1 is a circuit diagram of a conventional multi-voltage supply device.

2 is an automatic voltage supply circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

1: AC input unit 2: AC smoothing unit

3: fixed switching circuit section 4: variable switching circuit section

5: error amplifier unit 6: frequency discrimination circuit unit

7: fixed voltage output unit 8: variable voltage output unit

9: external signal discrimination unit 10: control unit

11: power supply R1: resistance

T1 ~ T6: transformer D1 ~ D5: diode

Q1 to Q4: Transistors C1 to C4: Condenser

The present invention relates to a monitor such as a TV, and more particularly to an automatic voltage supply circuit that can change the voltage according to the change of the main frequency of the monitor.

In multi-synchronous monitors, it is necessary to change the supply voltage applied to the oscillator circuit to match the oscillation frequency of the monitor according to the horizontal frequency variation applied to the monitor.

Therefore, in the conventional multi-voltage supply device, an AC smoothing part 2 for removing a ripple component of an AC current is connected to an AC input part 1 connected to a power source as shown in FIG. 1, and the AC smoothing part ( 2) is connected to a transformer T1 for inducing a current in the secondary transformer T3 of the fixed voltage output unit 7. The transformer T1 is connected to a fixed switching circuit section 3 which constantly controls the amount of current flowing in the transformer T1.

The AC smoothing unit 2 is connected to a transformer T2 for inducing a current in the two-side transformer T4 of the variable voltage output unit 8, and the current flowing through the transformer T2 is connected to the transformer T2. The variable switching circuit section 4 for controlling the amount is connected.

In addition, the variable switching circuit unit 4 determines the external frequency signal by the frequency discrimination circuit unit 6 which is configured at the rear end, and the frequency signal determined by the variable switching circuit unit 4 via the error ERROR amplifier unit 5. Configured to control.

The fixed voltage output unit 7 configured at the opposite position of the transformer T1 configures a secondary side transformer T3 for releasing current flowing through the transformer T1 at an opposite position of the transformer T1. The transformer T3 is connected to the rectifying diode D1 and the capacitor C1 for directing the alternating current induced in the transformer T3.

In addition, the variable voltage output section 8 configured at the opposite position of the transformer T2 constitutes a secondary transformer T4 for releasing current flowing through the transformer T2 at an opposite position of the transformer T2. The transformer T4 has a configuration in which a rectifier diode D2 and a capacitor C2 for directing an alternating current induced in the transformer T4 are connected.

In the conventional multi-voltage supply apparatus configured as described above, the AC current input is smoothed through the AC smoothing unit 2, and then the AC current fixed to the transformer T1 is flown by the fixed switching unit 3. Therefore, the AC current fixed in the transformer T1 is induced into the AC residual fixed in the secondary transformer T3, and the AC current induced in the secondary transformer T3 is rectified by the diode D1 and the capacitor C1. DC current through the output to a fixed DC current.

The AC current flowing through the transformer T2 through the AC smoothing unit 2 is varied by the control of the variable switching circuit 4 according to the frequency signal input to the monitor.

Accordingly, the alternating current that is varied through the transformer T2 is induced into an alternating current that is varied in the secondary side transformer T4, and the alternating current induced in the secondary side transformer T4 includes the rectifying diode D2 and the capacitor ( Through C2) it is output as a variable DC current.

However, even if one of the circuit components for supplying the fixed voltage or the variable voltage as described above does not operate, the other circuit portion continues to operate, resulting in the destruction of the set. In the case of requiring a variable voltage, the circuit configuration is complicated by using a separate switching circuit and a transformer, and there is a problem in that the PCB substrate must be expanded to meet the safety standard.

This design is to solve this problem, and the purpose of this design is to add auxiliary windings to existing transformers without using a separate switching circuit when different types of voltages are required for different frequency inputs. To get the voltage.

A feature of the present invention for achieving this object is an external signal discriminating unit for discriminating a frequency signal applied to the monitor according to each mode and outputting a low or high level signal, and an output voltage according to the output signal of the external signal discriminating unit. And an automatic voltage supply circuit including a control unit for controlling the power supply unit and a power supply unit for supplying power to the control unit.

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

FIG. 2 is an automatic voltage supply circuit diagram of the present invention. The external signal discriminating unit 9 for discriminating a frequency signal applied to a monitor according to each mode and outputting a low or high level signal has a low frequency signal applied to the monitor. An error amplifier unit 5 for outputting a low or high level control signal according to the output signal of the frequency discrimination circuit unit 6 is connected to the frequency discrimination circuit unit 6 for discriminating whether it is a frequency signal or a high frequency signal. .

In addition, the controller 10 for controlling the output voltage according to the output signal of the external signal discriminating unit 9 switches the transistor Q1 to the transistor Q1 to be driven according to the output signal of the external signal discriminating unit 9. As it is turned on, the switching transistor Q2 is turned on.

The transistor Q2 is connected such that an induced voltage is applied to the transformer T5 of the power supply unit 11 so that the induced voltage is output to the transformer T5 as the transistor Q2 is turned on.

Between the transistor Q2 and the output of the transformer T5, a current detection resistor R1 and an overcurrent prevention transistor Q3 which prevent an overcurrent from being applied to the transistor Q2 when an overcurrent is induced in the transformer T5. Configure by connecting.

In addition, a transistor Q4 for outputting a constant voltage is connected to an output terminal of the controller 10. The control unit 10 is connected to the outputs of the transformers T5 and T6 of the power supply unit 11 so that the diode D3 is turned on when the output voltage of the transformer T6 is higher than the output voltage of the transformer T5. Configure by connecting.

On the other hand, the power supply unit 11 which is connected to the control unit 10 and supplies power to the control unit 10 is the alternating current (T5) induced in the transformer (T5) transformer T5 for inducing an alternating current according to the frequency applied to the monitor The DC voltage is applied to the control unit 10 by connecting the rectifying diode D4 and the capacitor C3 to direct current.

In addition, the current supply unit 11 is a rectifier diode (D5) and a capacitor (C4) for directing the alternating current induced in the transformer (T6) the transformer (T6) for inducing an alternating current according to the frequency applied to the monitor It is configured to be connected to the DC voltage applied to the control unit 10. The transformer T6 is configured to induce a voltage less than that of the transformer T5.

According to the above-described scheme, when two kinds of frequencies are applied from the outside, the frequency discrimination circuit unit 6 identifies the high frequency signal and the low frequency signal and applies the corresponding signal to the air amplifier unit 5.

When the high frequency signal is input, the error amplifier unit 5 turns on the high level signal of the transistor Q1 of the control unit 10, and as the transistor Q1 is turned on, the base potential of the transistor Q2 decreases. The transistor Q2 is also turned on.

Therefore, an alternating current according to the frequency applied to the monitor is induced in the transformer T5, and the DC current is applied through the rectifying diode D4 and the condenser C3 so that the current applied to the transistor Q2 is turned on in the transistor Q2. As a result, it is output through the collector of transistor Q2.

In addition, the AC current induced through the transformer T6 is applied to the diode D3 by direct current voltage through the rectifying diode D5 and the capacitor C4, but the voltage induced through the lance T6 is applied to the transformer (D6). Since it is lower than the voltage induced through T5), the voltage induced in the transformer T6 is cut off by the diode D3 so that only the voltage induced in the transformer T5 is output.

When an excessive current is applied to the transformer T5, the base voltage of the transistor Q3 is lowered, and the transistor Q3 is turned on. Accordingly, the base potential of the transistor Q2 is increased, and the transistor Q2 is turned on. To prevent excessive voltage from being output.

Unlike the above, when a low frequency is input to the frequency discriminating circuit part 6, the frequency discriminating circuit part 6 applies the signal corresponding thereto to the error amplifier part 5. When the low frequency signal is input, the error amplifier unit 5 applies a low level signal to the base of the transistor Q1 of the controller 10. As the transistor Q1 is turned off and the transistor Q1 is turned off, The base potential of the transistor Q2 rises and the transistor Q2 is turned off.

Therefore, the alternating current induced by the transformer T5 is applied to the transistor Q2 by direct current through the rectifying diode D4 and the capacitor C3, but is not output as the transistor Q2 is turned off.

On the other hand, the alternating current induced through the transformer T6 is applied to the diode D3 by direct current through the rectifying diode D5 and the capacitor C4, and the transistor T2 is turned off because the transistor Q2 is turned off. Only the voltage induced in) is output.

Therefore, the present invention can obtain a multi-voltage by selecting a voltage induced on the transformer secondary side by controlling the control unit according to the signal determined by the frequency discrimination circuit unit.

As described above, the present invention selects and outputs a voltage induced in a transformer according to two kinds of frequency signals applied to a monitor, thereby eliminating the need for a switching circuit used in a conventional multivoltage supply device. The effect is that the device can be easily configured.

In particular, this invention describes the contents of supplying two voltages to two kinds of frequency signals. However, when multiple frequency discrimination circuits are configured and controlled, various multiple voltages can be easily obtained.

Claims (3)

An external signal discriminating unit 9 for determining a frequency signal applied to the monitor according to each mode and outputting a low or high level signal, and a control unit for controlling the output voltage according to the output signal of the external signal discriminating unit 9. And a power supply unit (11) for supplying power to the control unit (10). The frequency discriminating circuit section (6) according to claim 1, wherein the external signal discriminating section (9) includes a frequency discriminating circuit section (6) for discriminating whether a frequency signal applied to a monitor is a signal of a high frequency band or a signal of a low frequency band, and the frequency discriminating circuit section ( An automatic voltage supply circuit comprising an error amplifier section (5) for outputting a low or high level signal in accordance with the output signal of 6). The transistor of claim 1, wherein the controller 10 controls the output of the voltage turned on according to the output signal of the external signal discriminating unit 9 and induced in the transformer T5 of the power supply unit 11. Q1) and Q2, a transistor Q3 which prevents an overoutput voltage of the transformer T5 from being applied to the transistor Q2, and a transformer T6 output of the power supply unit 11, An automatic voltage supply circuit comprising a diode (D3) for controlling the output of the voltage induced in the transformer (T6), and a transistor (Q4) connected to the power supply (11) and the transistor (Q1) for outputting a constant voltage.