KR100829010B1 - Power Supply - Google Patents

Abstract

The present invention relates to a power supply device capable of controlling the power generation of the sub power supply unit using the primary side signal in the standby mode. In the power supply apparatus according to the present invention, the main switch unit configured on the primary side of the power supply unit is configured to control the operation of the sub switch unit by supplying a high logic signal generated in the standby mode to the sub switch unit through a pin. have. With such a simple control configuration, the present invention does not require a control configuration in standby mode by separating power from the primary side and the secondary side as in the prior art, and also has the effect of enabling the design of less than 1W of standby power consumption. .

Power supply, standby power consumption

Description

Power Supply

1 is a block diagram of a power supply according to the prior art,

2 is a block diagram of a power supply apparatus according to the present invention,

3 illustrates a relationship between a main switch unit and a sub switch unit according to the present invention;

Figure 4 shows an exemplary view of the main switch unit of the present invention.

Explanation of symbols on the main parts of the drawings

20: AC power input unit 22: First rectification-smoothing unit

24: sub switch unit 26: sub transformer

27,31: 2nd rectification-smooth part 28: main switch part

30: main transformer 32: feedback circuit

34; Burst mode detection unit 36; 1W signal pin

38: transistor 40; switch

The present invention relates to a power supply, and more particularly, to a power supply that is easy to design and implement while minimizing power consumption in a standby mode.

The biggest issue of modern electronic devices is the pursuit of eco-friendliness. In line with this, the regulation of power consumption is being tightened around the world. In particular, since the regulation on standby power consumption when the system is not in use is being tightened to the law, standby power consumption is an important part of the power supply design.

Recently, a power supply device which is widely used in electronic devices is a switching mode power supply (hereinafter referred to as 'SMPS'). The SMPS is a modular power supply device that converts electricity supplied from the outside into various electric devices such as computers, color televisions, video cartridge recorders (VCRs), exchangers, and wireless communication devices. Intermittent control at high frequency above the commercial frequency and plays a role in mitigating impact. The SMPS is advantageous in miniaturization and has high efficiency, so that it has become a main power supply device. The power supply described in the present invention is also the SMPS.

As shown in FIG. 1, a conventional power supply device includes a main power supply 12 and a sub power supply 10 for switching a primary voltage to generate a secondary voltage having a magnitude required by a product. have.

The main power supply unit 12 generates the secondary voltage in both the standby mode and the normal operation mode, but the sub power supply unit 10 generates the secondary voltage only in the normal operation mode and generates the secondary voltage in the standby mode. I never do that.

To this end, in the standby mode, the operation power supplied to the sub switch unit 13 located at the primary side of the sub power supply unit 10 is cut off under the control of the microcomputer 14. Since the sub-switch part 13 is not supplied with the operating power, the sub-switch part 13 is turned off, and thus the primary voltage supplied to the sub-transformer 11 is cut off.

In this operation, the conventional power supply device cuts off power generation of the sub power supply unit 10 and cuts off power consumption of the sub power supply unit 10. The microcomputer 14 operates by the secondary voltage generated by the main power supply unit 12.

The conventional power supply device operating as described above is divided into a primary voltage and a secondary voltage around the transformers 11 and 16 of the sub power supply 10 and the main power supply 12. At this time, the primary side voltage and the secondary side voltage are configured differently. That is, since the secondary voltage required by the product is generated using the primary voltage, the primary side and the secondary side are completely different from the transformers 11 and 16 of the sub power supply unit 10 and the main power supply unit 12. Power is used.

On the other hand, the conventional power supply device uses the control signal of the microcomputer 14 configured on the secondary side to control the power generation of the sub power supply unit 10 in the standby mode. That is, the control signal of the microcomputer 14 is configured to turn on / off the operation of the sub-switching unit 13 located on the primary side of the sub power supply unit 10.

However, as mentioned above, the power supply used by the microcomputer 14 and the power supply used at the primary side of the sub power supply unit 10 are completely different. Therefore, although not shown, the conventional power supply device separates the power supply on the secondary side and the primary side in order to control the operation of the sub-switch unit 13 on the primary side using the control signal of the microcomputer 14 located on the secondary side. There has been a problem in that an additional circuit consisting of a photo coupler, a capacitor, and a resistor is required.

In addition, the conventional power supply device has to separate the power supply on the secondary side and the primary side in order to control the operation of the sub-switch part 13 on the primary side using the secondary side control signal. At this time, there was a problem that the design of the SMPS composed of the primary side and the secondary side was complicated and difficult for power separation.

Accordingly, an object of the present invention is to provide a power supply device capable of controlling power generation of a sub power supply unit by using a primary signal in a standby mode.

According to an aspect of the present invention, there is provided a power supply apparatus including: a DC voltage generator configured to generate a first DC voltage from an AC voltage; A main power supply unit for interrupting the first DC voltage and generating a voltage for use in a normal mode and a standby mode; A sub power supply unit which interrupts the first DC voltage and generates a voltage for use in a normal mode; And a feedback circuit for feeding back the output voltage of the main power supply unit, wherein the main power supply unit generates a standby mode operation signal based on an output of the feedback circuit, and the standby mode operation signal is supplied to the sub power supply unit. It is characterized by blocking the voltage generation.

The main power supply unit of the present invention includes a pin for outputting a standby mode operation signal to the outside, and is supplied to the sub power supply unit through the pin.

The main power supply unit of the present invention includes a burst mode detection unit for outputting a high logic signal in the standby mode operation, characterized in that the high logic signal is output to the sub power unit through a pin.

The sub power supply unit of the present invention includes a first switch for controlling a first DC voltage; And a second switch for turning on / off an operating power of the first switch, wherein a high logic signal supplied through the pin turns on the second switch.

The second switch of the present invention is characterized by being a transistor.

The feedback circuit of the present invention is characterized by applying a value proportional to the output voltage of the main power supply to the burst mode detector.

And the main power supply unit of the present invention, the main switch for regulating the first DC voltage; And a main transformer generating a secondary voltage by the first DC voltage passing through the main switch, wherein the feedback circuit feeds back the secondary voltage of the main transformer.

In addition to the objects of the present invention as described above, other objects, other advantages and other features of the present invention will become apparent from the detailed description of the preferred embodiment in conjunction with the accompanying drawings.

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

2 shows a power supply according to a preferred embodiment of the present invention. Referring to FIG. 2, the power supply includes a first rectifier-smoothing unit 22, a primary rectifier 22, a main switch unit 28, and a main transformer connected in series to an AC (Alternative Current) voltage input unit 20 (AC input). Main Trans 30 and a second rectification-smooth 31. The main switch section 28, the main transformer 30, and the second rectifying-smoothing section 31 constitute a main power supply section that generates operating power in the standby mode and in the normal mode. And a feedback circuit 32 for monitoring the secondary voltage of the main transformer 30 and feeding it back to the main switch unit 28.

In addition, the power supply apparatus of the present invention comprises a sub power supply portion at the next stage of the first rectification-smoothing portion 22 in parallel with the main power supply portion. The sub power supply unit includes a sub switch unit 24, a sub trans 26, and a second rectification-smoothing unit 27. The sub power supply unit generates secondary power only in the normal mode of the system. In the standby mode, the power generation is interrupted by the high logic state signal generated from the main switch unit 28 to be described later, and power consumption is suppressed.

The AC voltage input unit 20 inputs a commercial AC voltage (eg, an AC voltage of 110 or 220 V) from the outside. The AC voltage input through the AC voltage input unit 20 is half-wave rectified or full-wave rectified by the first rectifying-smoothing unit 22, and then smoothed and converted into a DC voltage form. The DC voltage output from the first rectification-smoothing unit 22 maintains a constant level (eg, 110V or 220V). For convenience, the DC voltage generated at the first rectification-smoothing portion 22 is referred to as "first DC voltage".

The main switch unit 28 intercepts the first DC voltage to be supplied to the main transformer 30 by the first rectifying-smoothing unit 22 and converts it into a pulse width modulated signal form the main transformer 30 via the main transformer 30. The level of the voltage to be supplied to the second rectification-smooth portion 31 is adjusted. The main transformer 30 level converts an AC voltage in the form of a PWM signal supplied from the main switch unit 28 by the winding ratio between the primary side and the secondary side. The AC voltage in the form of a PWM signal level-converted by the main transformer 30 is rectified and smoothed by the second rectification-smoothing unit 31 and converted into a DC voltage.

The DC voltage generated by the second rectification-smoothing unit 31 is referred to as "second DC voltage" for convenience of description. The second DC voltage generated by the second rectification-smoothing unit 31 is determined by the ratio of the width of the high potential pulse to the AC voltage of the PWM signal type generated by the main switch unit 28 and the width of the low potential pulse. Variable. The second DC voltage generated in the second rectification-smoothing portion 31 is supplied to a circuit portion requiring a voltage in the product.

The feedback circuit 32 feeds back the secondary voltage of the main transformer 30, supplies a value corresponding to the feedback voltage to the main switch unit 28, and outputs a PWM signal output from the main switch unit 28. The main transformer 30 and the second rectifying-smoothing portion 31 are adjusted by allowing the voltage's impact coefficient (i.e., the ratio of the width of the high potential pulse to the width of the low potential pulse) to be adjusted large or small. ) To adjust the magnitude of the second DC voltage to be supplied to the circuit part in the product.

On the other hand, the secondary side of the main transformer 30 controls the generation of a large amount of voltage by performing an operation for generating power to be supplied to various circuit parts in the product during normal operation of the product. In addition, when the product enters the standby mode, only the power to be supplied to some of the circuit parts in the product needs to be generated. Therefore, by monitoring the secondary voltage or current of the main transformer 30, it is possible to detect whether the system is in normal operation or in the standby mode.

The feedback circuit 32 is configured to output a value proportional to the secondary side current (voltage) of the main transformer 30 to the main switch unit 28. In other words, the main switch unit 28 controls the output voltage of the main transformer 30 based on the value output from the feedback circuit 32.

Accordingly, the first direct current supplied to the sub transformer 11 through the sub switch unit 24 while the sub switch unit 24 is switched off by the high logic state signal of the main switch unit 28 in the standby mode. The voltage is cut off.

The operation for generating the secondary power supply of the sub power supply unit is performed in the same manner as the main power supply unit. However, the sub power supply does not generate secondary power in the standby mode. The operation at this time is as follows.

3 illustrates in detail the relationship between the main switch unit and the sub switch unit in the voltage supply device according to the present invention.

The main switch unit 28 includes a burst mode detector 34 that generates a high logic signal when the output signal of the feedback circuit 32 is in a low logic state. In addition, the main switch unit 28 includes a pin 36 for providing the output signal of the burst mode detection unit 34 to the sub switch 24. The pin 36 connects the main switch unit 28 and the sub switch unit 24.

The burst mode is an operation mode operated by the main switch unit in the standby mode for entering the low power mode of the system.

The sub switch unit 24 is a switch for supplying or cutting off the first DC voltage to the sub transformer 28 and a switch for opening and closing an operation power source for the on / off operation of the switch 40. PNP transistor 38 is included. The operation of the transistor 38 is controlled by the signal of the main switch unit 28 supplied through the pin 36.

The main switch unit 28 switches the primary side voltage supplied to the main transformer 30 based on the signal generated by the feedback circuit 32. The burst mode detector 34 is also configured to output a high logic signal based on the low logic signal generated by the feedback circuit 32 when the system enters the standby mode. The high logic signal output from the burst mode detector 34 controls the switching operation of a switching element (not shown) for switching the primary side voltage of the main transformer 30 to control the secondary output voltage of the main transformer 30. Adjust

On the other hand, the high logic signal output from the burst mode detector 34 turns the transistor 38 off through the pin 36 connecting the main switch 28 and the sub switch 24. To control. When the transistor 38 is controlled to be turned off, the switch 40 is turned off by cutting off the operating power of the switch 40. When the switch 40 is turned off, the primary DC voltage is cut off from being supplied to the sub transformer 26.

In contrast, when the system operates in the normal mode, the feedback circuit 32 generates a high logic signal. The high logic signal output from the feedback circuit 32 controls the burst mode detection unit 34 to output a low logic signal. The low logic signal output from the burst mode detection unit 34 is applied to the base terminal of the transistor 38 through the pin 36 connecting the main switch unit 28 and the sub switch unit 24. ) To turn on. When the transistor 38 is controlled in a turn-on state, operating power is supplied to the switch 40 through the transistor 38 so that the switch 40 is turned on. When the switch 40 is turned on, the primary DC voltage is supplied to the sub transformer 26 and the generation of the secondary voltage of the sub transformer 26 is resumed.

As described above, the present invention supplies the high logic signal generated in the standby mode to the sub switch unit 24 through the pin 36 in the main switch unit configured on the primary side of the power supply device. 24) to control the operation. An example of this invention is shown in FIG. 4. That is, as shown in the figure, the high logic signal generated in the burst mode operating in the standby mode is configured to be output to the outside via the 1W signal pin (1W-signal). The 1W signal pin is provided to the sub switch section 24.

As described above, the embodiments of the present invention have been described in the drawings, but this is merely exemplary, and those skilled in the art to which the present invention pertains various modifications without departing from the spirit and scope of the present invention. It will be apparent that other embodiments may be modified and equivalent. Accordingly, the scope of the present invention to be protected should be defined by the appended claims.

As described above, in the power supply apparatus according to the present invention, the main switch portion configured on the primary side of the power supply apparatus supplies the high logic signal generated in the standby mode to the sub switch portion through a pin to operate the sub switch portion. It is configured to control. With such a simple control configuration, the present invention does not require a control configuration in standby mode by separating power from the primary side and the secondary side as in the prior art, and also has the effect of enabling the design of less than 1W of standby power consumption. . In addition, since the control of the sub switch in the standby mode is performed on the primary side, the effect of simplifying the design can also be obtained.

Claims (7)

A DC voltage generator for generating a first DC voltage from the AC voltage; A main power supply unit for interrupting the first DC voltage and generating a voltage for use in a normal mode and a standby mode; A sub power supply unit which interrupts the first DC voltage and generates a voltage for use in a normal mode; And And a feedback circuit for feeding back the output voltage of the main power supply unit. And the main power supply unit generates a standby mode operation signal based on an output of a feedback circuit, and the standby mode operation signal blocks voltage generation of the sub power supply unit. The method of claim 1, The main power supply unit includes a pin for outputting a standby mode operation signal to the outside, and supplies the standby mode operation signal to the sub power unit through the pin. The method of claim 2, The main power supply unit includes a burst mode detection unit for outputting a high logic signal in a standby mode operation, wherein the high logic signal is output to the sub power unit through a pin. The method of claim 3, wherein The sub power supply unit, A first switch for interrupting the first DC voltage; And a second switch for turning on / off the operating power of the first switch, wherein a high logic signal supplied through the pin turns on the second switch. The method of claim 4, wherein The second switch is a power supply, characterized in that the transistor. The method of claim 3, wherein And the feedback circuit applies a value proportional to an output voltage of a main power supply to the burst mode detector. The method of claim 1, The main power supply unit, A main switch for interrupting the first DC voltage; It is configured to include a main transformer for generating a secondary voltage by the first DC voltage passed through the main switch, The feedback circuit feeds back the secondary voltage of the main transformer.

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