KR920006432Y1 - Switching mode power supply - Google Patents

Abstract

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Description

Standby mode switching mode power supply

1 is a conventional circuit diagram.

2 is a circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

100: large SMPS 101, 103, 201, 204: 1-5 rectifier

102, 202: 1-2 SMPS driver 206, 207: 1-2 controller

205, 208, 209: 1-3 regulator T1-T3: 1-2 transformer

RY1, RY2: relay D1-D3: diode

Q1-Q2: transistor R1-R2: resistor

The present invention relates to a switching power supply. In particular, in a power supply having a large switching mode power supply (SMPS) and a small SMPS, the secondary power supply of the small SMPS is used to standby the AC input power. The present invention relates to a power supply unit capable of functioning and outputting a stable voltage.

As shown in FIG. 1, the conventional SMPS includes a first bridge diode 11, a first SMPS driver 12, a first transformer 13, and a first rectifier 14 to supply large power. A small SMPS 20 that is configured of a large SMPS 10, a second bridge diode 21, a first SMPS driver 22, a second transformer 23, and a second rectifier 24 to supply small power. ), A standby SMPS 40 for supplying standby power, comprising a rectifier diode 31, a third SMPS driver 32, a third transformer 32, and a third rectifier 33, and a microcomputer. (Not shown) The control unit 40 controls the input power by a control signal, and the switch SW1 switches the input AC input power by the control signal of the control unit 40.

Referring to the operation based on the above configuration, the AC input power is applied to the standby SMPS 30 to output the standby power. The power output from the standby SMPS 30 is input to the controller 40. At this time, when a control signal of a microcomputer (not shown) is input through the input terminal P1, the controller 40 generates a control signal to switch the switch SW1. At this time, when the controller 40 outputs a "high" signal, the switch SW1 is turned on, and when the controller 40 outputs a low signal, the switch SW1 is turned off. When the switch SW1 is turned on, the input AC power is applied to the large SMPS 10 and the small SMPS 20 to output different voltages.

In the conventional circuit as shown in FIG. 1, since the large SMPS 10, the small SMPS 20, and the standby SMPS 30 are respectively configured, noise ripple is generated by the switching oscillation frequency according to power switching, and the circuit becomes complicated. There was a problem.

Therefore, the objective of the present invention is to enable a small SMPS to be used in combination with a standby SMPS in a switching mode power supply device having a large SMPS and a small SMPS, thereby simplifying a circuit and reducing noise due to switching oscillation frequency. In providing SMPS.

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

FIG. 2 is a circuit diagram according to the present invention, and includes a first rectifying base 101, a first SMPS 102, a first transformer T1, and a second rectifying unit 103. A third rectifier 201 for rectifying AC power to output a DC voltage; and a second SMPS driver for inputting the output of the third rectifier 201 to drive the SMPS. 202 and the second transformer T2 for inducing the primary side voltage output from the third rectifying unit 201 to the secondary side by the driving signal of the second SMPS driver 202 and the second transformer T2. A third regulator for rectifying the induced voltage to the secondary side and outputting a DC voltage to input the output voltages of the fourth to fifth rectifiers 203 and 204 and the fifth rectifier 204 to supply a standby power supply. 206 and a first switch 2 for supplying an AC input voltage to the large SMPS 100 by switching driving by a control signal input through the input terminal P2. 06) and a second switching unit 207 for switching and outputting the output voltages of the fourth to fifth rectifying units 203 and 204, respectively, by the control signal input through the input terminal P2, and the second switching unit 207. The first and second regulators 208 and 209 outputting a predetermined voltage by inputting the output voltage of the fifth rectifying unit 204 switched by the output.

In the above configuration, the first switching unit 206 includes two diodes D1-D2 and a transistor Q1 relay RY1, and the second switching unit 207 has two switches SW1-SW2 interlocked with each other. It consists of a relay TY1, a diode D3, and a transistor Q2.

An embodiment of the present invention will be described with reference to FIG. 2 based on the above configuration. When AC power is input, the third rectifying unit 201 rectifies and outputs a DC voltage.

The output DC voltage of the third rectifier 201 is applied to the second SMPS driver 202 through the resistor R1 to drive the second SMPS driver 202. When the second SMPS driver 202 is driven, the second transformer T2 induces the primary voltage output from the third rectifier 201 to the secondary side.

The fourth to fifth rectifiers 203 and 204 respectively input the induced voltages to the secondary side of the second transformer T2 to rectify and output DC voltages, respectively.

The fourth rectifier 203 flows the output voltage through the resistor R1.

In addition, the output voltage of the fifth rectifier 204 is applied to the supply power (B ⁺ ) of the relays TY1-TY2 and is input to the third regulator 205 to supply the standby power. At this time, when the power is turned on, a high signal is input through the input terminal P1 and applied to the bath of the transistor Q1 through the diode D2. This turns on the transistor Q1. When the transistor Q1 is turned on, the relay TY1 is turned on, so AC power is applied to the large SMPS 100.

Accordingly, the AC input power supplies a large power voltage through the first rectifier 101, the first SMPS driver 102, the first transformer T1, and the second rectifier 103. In addition, the high signal input through the input terminal P2 turns on the transistor Q2. When the transistor Q2 is turned on, the relay RY2 is turned on to switch the switches SW1 and SW2 interlockedly.

As a result, the output voltage of the fourth rectifying unit 203 is output to the predetermined load through the switch SW1, and the output voltage of the fifth rectifying view 204 is also output through the switch SW2. The voltage output through the switching SW2 is applied to the load by outputting a desired predetermined voltage by driving the 1-2 regulators 208 and 209.

However, when the power is turned off, a low signal is input through the input terminal P2 to turn off the transistors Q1-Q2. When the transistors Q1-Q2 are turned off, the relays RY1-RY2 are turned off, so that power is cut off from the large SMPS 100 or the 1-2 regulators 208, 209 and output to the third regulator 205. Only bi-power is supplied,

As described above, the SMPS having the large SMPS and the small SMPS can be used in combination with the standby SMPS, thereby reducing noise due to the oscillation frequency and reducing the circuit, thereby reducing the cost. There is an advantage.

Claims (4)

A standby mode switching mode power supply having a large SMPS (100) for inputting AC power to supply a large power, comprising: a third control unit (201) for rectifying AC power and outputting a DC voltage, and the third rectifying unit The second SMPS driver 202 for inputting the output of the 201 to drive the SMPS and the primary side voltage output from the third rectifier 201 by the drive signal of the second SMPS driver 202 to the secondary side. 4-5 rectifiers 203 and 204 for rectifying the second transformer T2 to be induced, the voltage induced to the secondary side of the second transformer T2, and outputting a DC voltage, respectively, and the fifth rectifier 204. A third regulator 206 for supplying a standby power by inputting an output voltage of the first and a first regulator for supplying an AC input voltage to the large SMPS 100 by switching and driving by a control signal input through the input terminal P2. The fourth to fifth tablets are controlled by the switching unit 206 and the control signal input through the input terminal P2. A predetermined voltage is input by inputting the second switching unit 207 for switching and outputting the output voltages of the current flow units 203 and 204 and the output voltage of the fifth rectifying unit 204 switched and output by the second switching unit 207. Standby combined switching mode power supply, characterized in that consisting of the first to second regulators (208,209) for outputting. The method of claim 1, wherein the first switching unit 206 comprises a first switching means for switching according to the input state of the control signal, and a relay (RY1) for switching the AC input power by the switching of the switching means. Standby mode switching mode power supply. The method of claim 1, wherein the second switching unit 207 comprises a second switching means for switching according to the input state of the control signal, and a relay (RY2) capable of supplying a predetermined voltage by the switching of the switching means. Standby combined switching mode power supply. The standby mode switching mode power supply according to claim 3, wherein the relay (RY2) switches in conjunction with the switching (SW1) and (SW2).