KR960008014Y1 - Power supply circuit of monitor - Google Patents

Abstract

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Description

Power Supply Circuit for Multi Scan Monitor

1 is a conventional power supply circuit diagram.

2 is a power supply circuit diagram of the present invention.

* Explanation of symbols for main parts of the drawings

11: horizontal oscillator 12: mode selector

13 power supply 14 horizontal deflection output

15: high voltage output unit 16: resonance selection unit

SW ₁₁ , SW ₁₂ : Selection switch C ₁₄ ~ C ₁₆ : Condenser

The present invention is a horizontal deflection output unit for controlling the horizontal deflection of the electron beam of the cathode ray tube in a multi-scan monitor and TV receiver used as a screen display device in a computer system, and a high pressure to generate high pressure to supply to each part including the cathode ray tube The present invention relates to a power supply circuit of a multi-scan monitor that supplies operating power to an output unit, and more particularly to a power supply circuit of a multi-scan monitor that supplies operating power to a horizontal deflection output unit and a high voltage output unit as a single power supply. .

In the conventional power supply circuit, as shown in FIG. 1, a horizontal oscillation unit 1 oscillates to generate a horizontal synchronizing signal, and an operation mode is determined by output signals of the horizontal oscillation unit 1 to output a selection signal. A horizontal deflection power supply unit 3 and a high voltage power supply unit 4 for supplying a horizontal deflection power source and a high voltage generation power source in accordance with a mode selection unit 2 and an output signal of the mode selection unit 2; A horizontal output transistor (Q ₁ ), a diode (D ₁ ), a capacitor (D ₁ ) for controlling the horizontal deflection according to the oscillation signal of the horizontal oscillation unit (1) as the operating power of the horizontal deflection power supply unit (3). C ₁ , C ₂ ), the horizontal deflection output unit 5 of the dummy transformer L ₁ and the horizontal deflection coil HDY ₁ , and the output power of the high voltage power supply unit 4 as an operating power source. the high-voltage output transistor (Q ₂₎ for generating a high voltage in accordance with the oscillation signal of the oscillator 1, Eau (D _2, D _3), were made up of the capacitor (C ₃₎ and a flyback transformer (FBT ₁₎ to the high-voltage output section 6.

In the conventional power supply circuit configured as described above, the horizontal oscillator 1 oscillates to output a horizontal synchronizing signal, and the mode selector 2 determines an operation mode at the frequency of the output horizontal synchronizing signal to output a selection signal. The horizontal deflection power supply unit 3 outputs one of the operating power sources V ₁₁ , V ₁₂ , and V ₁₃ according to the selection signal of the mode selection unit 2, and applies it to the horizontal deflection output unit 5 as an operating power source. In addition, the high-voltage power supply unit 4 also outputs one of the operating power (V ₂₁ , V ₂₂ , V ₂₃ ) according to the selection signal of the mode selector 2 to output the operating power to the high-voltage output unit 6. Will be authorized.

Then, the transistor Q ₁ of the horizontal deflection output unit 5 is turned on and off according to the transmission signal of the horizontal oscillation unit 1, and the damper diode D ₁ , the resonance capacitor C ₁ , and the horizontal deflection coil HDY. ₁ ) and the correction capacitor (C ₂ ) are operated to generate sawtooth current, and the sawtooth current flows through the horizontal deflection coil (HDY ₁ ) to control the horizontal deflection of the electron beam of the cathode ray tube. The transistor Q ₂ of the unit 6 is also turned on and off in response to the oscillation signal of the horizontal oscillation unit 1, and 1 of the damper diode D ₂ , the resonance capacitor C ₂ , and the flyback transformer FBT ₁ . The high voltage pulse signal is generated in the collector of the transistor Q ₂ by the difference coil, and the generated high voltage pulse signal is rectified by the boost and diode D ₃ in the flyback transformer FBT ₁ .

In this case, the horizontal deflection power supply unit 3 and the high voltage power supply unit 4 operate according to the selection signal of the mode selection unit 2, and the operating power sources V ₁₁ , V ₁₂ , V ₁₃ , (V ₂₁ , V ₂₂ , The reason for selectively outputting any one of V ₂₃ ) and applying it to the horizontal deflection output unit 5 and the high voltage output unit 6 as an operating power source will be described.

The horizontal deflection current I (t) flowing through the horizontal output transistor Q1 and the collector voltage Vcp generated in the collector of the high voltage output transistor Q2 are expressed by the following equations (I) and (II).

I (t) = (V ₁ / L ₁₁ ) tS -------------- (Ⅰ)

Vcp = {1+ (π / 2) (ts / tr)} V2 -------------- (II)

Here, V ₁ and V ₂ are the output power of the horizontal deflection power supply 3 and the high voltage power supply 4, ts is the scanning time, and tr is the retrace time.

As can be seen from Equations (I) and (II) above, in order to generate a desired horizontal deflection current and high voltage during multi-scan, power applied to the horizontal deflection output unit 5 and the high voltage output unit 6 according to the operation mode. To this end, in the related art, a horizontal deflection power supply unit 3 and a high voltage power supply unit 4 according to an operation mode are conventionally operated power sources V ₁₁ , V ₁₂ , V ₁₃ , V ₂₁ , V ₂₂ , and the like. V ₂₃ ) to selectively output either.

However, in the conventional power supply circuit as described above, in order to supply power suitable for the horizontal deflection output unit 5 and the high voltage output unit 6 according to each operation mode, a separate power supply source, that is, a horizontal deflection power supply unit and Since the high voltage power supply unit was configured to supply power, it was difficult to manufacture a power supply source, and the circuit configuration was complicated, resulting in an increase in the production cost of the product.

The present invention has been made to solve the above-mentioned conventional problems, and constitutes a resonance selector having several capacitors and select switches at the high voltage output unit, and the select switch is selectively connected according to the select signal of the mode selector. By selectively connecting several capacitors to the high voltage output unit and varying the resonant frequency, an object thereof is to provide a power supply circuit for supplying the operation power of the horizontal deflection output unit and the high voltage output unit to one power source. It will be described in detail with reference to the drawings of FIG.

2 is a power supply circuit diagram according to the present invention, which generates a horizontal synchronizing signal by oscillating as shown therein, and outputs a selection signal by determining an operation mode based on an output signal of the horizontal oscillating unit 11. The horizontal oscillation unit 11 uses a mode selection unit 12, a power supply unit 13 for supplying power in accordance with the output signal of the mode selection unit 12, and an output power of the power supply unit 13 as an operating power source. ) Consists of a horizontal output transistor (Q ₁₁ ), a diode (D ₁₁ ), a capacitor (C ₁₁ , C ₁₂ ), a dummy transformer (L ₁₁ ), and a horizontal deflection coil (HDY ₁₁ ) to control the horizontal deflection according to the oscillation signal A high voltage output transistor Q ₁₂ and a diode generating a high voltage according to the oscillation signal of the horizontal oscillation output unit 14 and the output power of the high voltage generating power supply unit 14 as operating power. (D _12, D _13), the capacitor (C _13), and a flyback transformer (FBT ₁₁₎ A was composed of the high-voltage output section 15, and a resonance selector 16 for varying the resonant frequency of the high-voltage output unit 15 in accordance with the selection signal from the mode selection unit (12).

In the resonator selection unit 16, a capacitor (C _14), and a selection switch (SW _11), the capacitor through, respectively the (SW ₁₂₎ (C _14), capacitor (C ₁₅₎ (C ₁₆₎ being connected to And the selection switch SW ₁₁ (SW ₁₂ ) is configured to be selectively connected in accordance with the selection signal of the mode selection unit 12.

In the power supply circuit of the present invention, the horizontal oscillation unit 11 oscillates and outputs a horizontal synchronizing signal, and the output horizontal synchronizing signal is a transistor (Q) of the horizontal deflection output unit 14 and the high voltage output unit 15. ₁₁ ) (Q ₁₂ ) and is applied to the mode selector 12, so that the mode selector 12 determines the operation mode at the frequency of the horizontal synchronization signal applied, outputs a selection signal, and outputs the selected signal. Accordingly, the power supply unit 13 selectively outputs power B ₁₁ , B ₁₂ , and B ₁₃ .

Then, the transistor Q ₁₁ of the horizontal deflection output unit 14 is turned on and off in response to the oscillation signal of the horizontal oscillation unit 11, and the damper diode D ₁₁ and the resonance capacitor C ₁₁ horizontal deflection coil HDY _11. ) And the correction capacitor C ₁₂ are operated to generate sawtooth current, and the sawtooth current flows through the horizontal deflection coil HDY ₁₁ to control the horizontal deflection of the electron beam of the cathode ray tube.

In addition, the transistor Q ₁₂ of the high voltage output unit 15 is also turned on and off according to the oscillation signal of the horizontal oscillation unit 11 while the damper diode D ₁₂ , the resonance capacitor C ₁₂ , and the flyback transformer FBT _11. The high pressure pulse signal is generated in the collector of the transistor Q ₁₂ by the primary coil of the C, and the generated high voltage pulse signal is rectified by the boost and diode D ₁₃ in the flyback transformer FBT ₁₁ .

Here, a power supply necessary for the horizontal deflection output unit 14 to generate a desired horizontal deflection current I (t), and a power supply for obtaining the high voltage desired by the high voltage output unit 15, that is, the collector voltage Vcp of the transistor Q ₁₂ . In order to do the same, the retrace time tr may be changed. According to the present invention, when the power supply unit 13 is in the first mode of outputting the power B ₁₁ , the selection signal of the mode selection unit 12 is changed. Resonance selector 16 in the second mode in which both select switches SW ₁₁ and SW ₁₂ of resonance selector 16 are opened, only capacitor C ₁₄ is operated, and outputs power B ₁₂ . ), The select switch SW ₁₁ is connected, the select switch SW ₁₂ is opened to allow the capacitors C ₁₄ and C ₁₅ to be connected and operated in parallel, and to output a power source B ₁₁ . In this case, the selector switches SW ₁₁ and SW ₁₂ of the resonance selecting unit 16 are all connected to the capacitors C ₁₄ to C. The retrace time tr is varied while allowing ₁₆ to be connected and operated in parallel.

As described in detail above, the present invention simplifies the circuit configuration by supplying the operating power to the horizontal deflection output unit and the high voltage output unit as one power source by varying the resonant frequency, that is, the retrace time, of the high voltage output unit according to the operation. And, the manufacturing is simple, there is an effect such as to reduce the production cost of the product.

Claims (2)

A horizontal oscillator 11 for generating a horizontal synchronization signal, a mode selector 12 for outputting a selection signal by discriminating an operation mode from the output signal of the horizontal oscillator 11, and an output of the mode selector 12 A power supply 13 for supplying power in accordance with the signal, and a horizontal deflection output 14 for controlling the horizontal deflection in accordance with the oscillation signal of the horizontal oscillation unit 11 and the output power of the power supply 13 as the operating power. And the high voltage output unit 15 generating the high voltage according to the oscillation signal of the horizontal oscillation unit 11 and the output power of the high voltage generation power supply unit 14 as an operating power source, and the mode selection unit 12. And a resonance selector (16) for varying the resonant frequency of the high voltage output unit (15) according to the selection signal of the multi-scan monitor. The method of claim 1, wherein the resonant selector 16 is a capacitor (C ₁₅₎ through a capacitor (C _14), and a selection switch (SW ₁₁₎ (SW ₁₂₎ respectively connected to said capacitor (C ₁₄₎ ( C ₁₆ ), wherein the selection switch (SW ₁₁ ) (SW ₁₂ ) is configured to be selectively connected according to the selection signal of the mode selection unit (12).