KR100464164B1 - Resonant Power Supply for Multi Sync Monitor - Google Patents

Abstract

The present invention relates to a resonant power supply configured to be used in a multi-sync monitor, wherein a resonant power supply having high power efficiency and low switching noise can be used only in a monitor having a single horizontal frequency signal, and a plurality of horizontal frequency signals In the multi-sink monitor with a variable resonant frequency by varying the inductance of the capacitor and inductance used to generate the resonant frequency to form a resonant power supply by varying the resonant frequency, The device is capable of responding to various frequency signals, allowing it to be used as a power source for monitors with multiple horizontal frequency signals.

Description

Resonant Power Supply for Multi Sync Monitor

The present invention relates to a resonant power supply, and more particularly, to a resonant power supply configured to be used in a multi-sync monitor.

In general, there are monitors using a single horizontal signal frequency and multi-sync monitors using a plurality of horizontal signal frequencies. Such monitors mainly use a flyback converter type power supply.

However, since the loss of the monitor power supply increases at a time when the frequency of the monitor is continuously increasing to reduce the fatigue of the user's eyes, there is a limit to the use of the flyback converter type power supply.

Therefore, even if the monitor frequency is increased, the need for a power supply device with low loss of the power supply device is required, and a representative high efficiency power supply device is a resonance power supply device.

The resonant power supply can overcome the limitations of the flyback converter type power supply due to high power efficiency and low switching noise, but the operating frequency is determined by the unique resonant frequency of the resonant power supply circuit. Although it can be used for a monitor having a horizontal signal frequency, there is a problem in that it cannot be used for a monitor having a plurality of horizontal frequency signals.

An object of the present invention is to provide a resonant power supply device that can be used in a monitor having a plurality of horizontal frequency signals.

That is, by changing the inductance of the capacitor and inductance used for generating the resonant frequency in the resonant power supply in a variable manner so that the resonant frequency is generated variably, it is possible to cope with a variety of frequency signals, so that a plurality of horizontal frequencies A resonant power supply was constructed to be used as a power source for monitors with signals.

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

FIG. 1 is a circuit diagram showing the configuration of the present invention. An input rectifying unit 1 is connected to a signal output terminal of an input rectifying unit 1 and a rectifying unit for primary rectifying and outputting a DC voltage. A switching unit 2 for receiving and switching a DC power signal output from the switching unit to generate and output a high frequency signal, and a high frequency signal output from the switching unit 2 connected to the signal output terminal of the switching unit 2. A variable resonant frequency generator 3 that receives the variable resonant frequency and outputs the signal, and is connected to a signal output terminal of the variable resonant frequency generator 3 and receives a signal generated by the variable resonant frequency generator 3 and outputs a voltage. A transformer rectifier 4 for varying the level and outputting the second transformer rectifier 5 which is connected to the signal output terminal of the transformer 4 and receives a signal output from the transformer 4 and rectifies and outputs the secondary rectified signal; , A monitor 6 connected to the signal output terminal of the secondary rectifier 5 to receive and display a signal output from the secondary rectifier 5, and a secondary rectifier connected to the signal output terminal of the secondary rectifier 5; A variable resonant frequency generator by a feedback circuit section 7 for feeding back the output signal of (5) and a synchronization signal output from the monitor 6 simultaneously connected to the signal output terminals of the monitor 6 and the feedback circuit section 7; (3) A variable resonant frequency control section 8 for controlling the resonant frequency value generated at the same time, and a synchronization signal and feedback output from the monitor 6 by being simultaneously connected to the signal output terminals of the monitor 6 and the feedback circuit section 7 It comprises a switching control unit 9 for controlling the switching of the switching unit 2 by the feedback signal output from the circuit unit (7).

The switching unit 2 includes a source grounding type field effect transistor 1 (FET1) having a gate terminal connected to the signal output terminal of the switching control unit 9, and a transformer connected to the drain terminal side of the field effect transistor 1 (FET1). A field effect transistor 2 (FET2) having a gate and a source terminal connected by the transformer 1 (21), a drain terminal connected to a signal output terminal of the input rectifier 1, and the transformer 1 (21); The gate and source terminals are connected to each other, and the drain terminal includes a field effect transistor 3 (FET3) connected to the source terminal of the field effect transistor 2 (FET2) in parallel with the transformer 1 (21).

The variable resonant frequency generator 3 is connected to the source terminal of the field effect transistor 2 (FET2) of the switching unit 2 in parallel with the field effect transistor 3 (FET3) and the signal output terminal of the resonant frequency controller 8 Transformer 2 31 connected to the transformer 4 and connected to the transformer 4, the negative side of which is connected in parallel with the field effect transistor 2 (FET2) to the signal output terminal of the input rectifier 1, and the positive side of the transformer 4; And a capacitor 1 (C1) connected in parallel with the transformer 4 on the + side of the diode 1 (D1) and connected to a source terminal of the field effect transistor 3 (FET3). And a diode 2 (D2) connected in parallel with the capacitor 1 (C1).

In the above, the transformer 2 31 has a value that is changed by the output of the resonance frequency control unit 8 as an inductance for generating the resonance frequency.

The secondary rectifier 5 includes the rectifier 1 (51) and the rectifier 2 (52).

The rectifier 1 (51) is connected to the diode 3 (D3) connected to the output terminal of the transformer unit 4, the + side is connected to the output terminal of the transformer unit 4, the + side is parallel to the diode 3 (D3) Connected to the diode 4 (D4), the capacitor 2 (C2) simultaneously connected to the output of the transformer side 4 and the negative side of the diode 3 (D3) and the diode 4 (D4), and the diode 3 (D3) Reactance 1 (L1) connected in parallel with capacitor 2 (C2) on the negative side of diode 4 (D4), and capacitor 3 (which is simultaneously connected to the other side of capacitor 1 (C2) and the other side of capacitor 2 (C2) ( C3).

Rectifier 2 (52) is the same configuration as the rectifier 1 (51), diode 5 (D5), diode 6 (D6), capacitor 4 (C4), reactance 2 (L2), capacitor 5 (C5) )

In the operation of the resonance type power supply as described above, when the field effect transistor 2 (FET2) of the switching unit 2 is turned on, the field effect transistor 3 (FET3) is turned off, and the field effect transistor 2 (FET2) is turned on. In FIG. 2, the voltage output from the input rectifier 1 is charged to the capacitor 2 (C2) of the variable resonance frequency generator 3, and when the field effect transistor 3 (FET3) is turned on, the voltage charged to the capacitor 2 (C2) is applied. Through the process of discharging and outputting to the transformer unit 4, the switching unit 2 converts the DC voltage output from the input rectifier 1 into a high frequency voltage and outputs the high frequency voltage to the transformer unit 4.

When the high frequency voltage is applied to the transformer unit 4 by the above process, the transformer unit 4 converts the voltage output from the switching unit 2 and outputs the voltage to the secondary rectifier unit 5, and the secondary rectifier unit 5. The voltage output from the transformer 4 is divided into diodes 3 (D3), diodes 4 (D4), diodes 5 (D5), diodes 6 (D6) and capacitors 2 (C2) and capacitors 4 ( It rectifies by C4), removes a high frequency component, and outputs it to the monitor 6. As shown in FIG.

The monitor 6 receives and processes a signal output from the secondary rectifier 5 and displays it, and outputs a synchronous signal to the variable resonance frequency controller 8 and the switching controller 9. In addition, the feedback circuit unit 7 receives the output of the secondary rectifier 5 and outputs it to the variable resonant frequency controller 8 and the switching controller 9.

As described above, when the synchronization signal and the feedback signal are input from the monitor 6 and the feedback circuit unit 7, the switching control unit 9 analyzes the input signal to turn on / off the field effect transistor of the switching unit 2 and thereby the switching unit. The operation of (2) is controlled.

On the other hand, the variable resonant frequency controller 8 analyzes the input signal, calculates a circuit element value for generating a resonant frequency signal corresponding to the horizontal frequency signal currently being used by the monitor 6, and calculates the circuit element value based on the calculated circuit element value. The control signal is output to the transformer 1 (21) of the variable resonant frequency generator (3).

When the inductance value of the arbitrary level is output by the signal output from the variable resonant frequency controller 8 in the transformer 1 (21), the resonant frequency is determined by the output value of the transformer 1 (21) and the output value of the resonance capacitor 1 (C1). Is generated.

In the above process, the output value of the variable resonant frequency controller 8 is changed by the output signal of the monitor 6, the output value of the transformer 1 21 is changed by the output value of the variable resonant frequency controller 8, and thus the variable resonant frequency is changed. The output resonance frequency of the generator 3 changes.

That is, the resonant frequency signal varies in response to various horizontal frequency signals of the monitor 6.

As described above, the present invention enables the resonant power supply to be used in a multi-sync monitor.

As described above, the present invention configures a resonant power supply by changing the inductance among the capacitor and inductance used for generating the resonant frequency in a variable manner, thereby multiplying the resonant power supply with high power efficiency and low switching noise. This has the effect of making it available to the sink monitor.

1 is a circuit diagram showing a configuration of the present invention.

<Description of Symbols for Major Parts of Drawings>

1: input rectifier 2: switching unit

3 variable resonant frequency generator 4 transformer

5: secondary rectifier 6: monitor

7: feedback circuit section 8: variable resonant frequency control section

9: switching control unit 21: transformer 1

31 Transformer 2 51 Rectifier 1

52: Rectifier 2 FET 1: Field Effect Transistor 1

FET2: field effect transistor 2 FET3: field effect transistor 3

D1: Diode 1 D2: Diode 2

D3: Diode 3 D4: Diode 4

D5: Diode 5 D6: Diode 6

C1: Capacitor 1 C2: Capacitor 2

C3: Capacitor 3 C4: Capacitor 4

C5: Capacitor 5 L1: Reactance 1

L2: Reactance 2

Claims (3)

It is connected to the signal output terminal of the input rectifier (1) and the input rectifier 1 for outputting a DC voltage by primary rectifying the power input from the outside, and receives and switches the DC power signal output from the input rectifier 1 A switching unit 2 for generating and outputting a high frequency signal, and a variable resonance frequency generator for receiving a high frequency signal variably resonating and outputting the high frequency signal output from the switching unit 2 connected to the signal output terminal of the switching unit 2. (3) and a transformer unit (4) connected to the signal output terminal of the variable resonance frequency generator (3) to receive a signal generated by the variable resonance frequency generator (3) and output the signal by varying the voltage level; And a secondary rectifying unit 5 connected to the signal output terminal of the transformer unit 4 and receiving a signal output from the transformer unit 4 to rectify and output the secondary rectifying unit 5 to a signal output terminal of the secondary rectifying unit 5. Connected A monitor 6 for receiving and displaying a signal output from the secondary rectifier 5 and a feedback circuit 7 connected to the signal output terminal of the secondary rectifier 5 to feed back the output signal of the secondary rectifier 5. ) And a variable for controlling the resonant frequency value generated in the variable resonant frequency generator 3 by a synchronous signal output from the monitor 6 by being simultaneously connected to the signal output terminals of the monitor 6 and the feedback circuit unit 7. The switching unit is connected to the resonant frequency control unit 8 and the signal output terminal of the monitor 6 and the feedback circuit unit 7 by a synchronization signal output from the monitor 6 and a feedback signal output from the feedback circuit unit 7. And a switching control unit (9) for controlling the switching of (2). 2. The variable resonant frequency generator (3) according to claim 1, wherein the variable resonant frequency generator (3) is connected in parallel to the source terminal of the field effect transistor (FET2) and in parallel with the field effect transistor (FET3). A transformer 2 31 connected to the transformer 4 and a negative side connected to the signal output terminal of the input rectifier 1 in parallel with a field effect transistor 2 (FET 2), and a positive side of the transformer 4. A capacitor 1 (D1) connected to the diode 1, a capacitor 1 (C1) connected in parallel with the transformer 4 on the + side of the diode 1 (D1), and connected to a source terminal of the field effect transistor 3 (FET3); And a diode 2 (D2) connected in parallel with the capacitor 1 (C1). 3. The resonant power supply device for a multi-sink monitor according to claim 2, wherein the transformer (2) has a value that is changed by the output of the resonant frequency controller (8) with an inductance for generating a resonant frequency.

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