KR101194466B1 - Power apparatus and method of supplying power - Google Patents

Abstract

The present invention provides a power supply including a switching unit, a bleeder resistor, a filter, a rectifier, a power factor corrector, an output capacitor, a rectifier diode, a surge absorber, a main power supply, and a standby power supply. In addition, the AC power is charged to the output capacitor by the rectifier diode and the surge absorber so that the standby power supply generates the standby power while the switching unit is turned off. In addition, AC power is charged to the power capacitor through the switching section, the bleeder resistor, the filter, the rectifier and the power factor corrector so that the main power supply generates the main power while the switching section is turned on. The present invention also provides a power supply method.

Description

POWER APPARATUS AND METHOD OF SUPPLYING POWER}

The present invention relates to a power supply and a power supply method, and more particularly, to a power supply and a power supply method that operates in an effective manner while the electronic device is in the standby mode.

In general, electronic devices typically include a power supply and a load, and the power supply converts AC power into power required for the load. However, the power supply is very fragile, easily affected by surge voltage pulses and generates a large current, thus damaging the load device at the end. To prevent this phenomenon, the conventional method is to apply a surge absorber and a fuse to suppress the surge voltage pulse. 1, a block diagram of a power supply in accordance with the prior art is shown.

The conventional power supply 1 can function to supply power in standby mode or normal mode. The electrical plug of the electronic device is connected to a power outlet, and the AC power is transmitted to the conventional power supply 1, so that the fuse 11, the bleeder resistor 13, the filter 12, the surge absorber 10, the rectifier Through 14 and diode D1, voltage Vc is generated at capacitor Co. On the other hand, the standby power supply 19 generates standby power (STB power) with respect to the voltage Vc to supply power to the load 3. The conventional power supply 1 operates in the standby mode. In view of the embodiments described above, a surge absorber 10 is used to suppress temporary surges in the current occurring at the moment of connecting the electrical plug to the power outlet.

In addition, while the switch S1 is in a conducting state and the power factor corrector 16 is activated, the conventional power supply 1 operates in a normal mode to supply power. At the same time, AC power is delivered to the conventional power supply 1, such as switch S1, fuse 11, bleeder resistor 13, filter 12, surge absorber 10, rectifier 14 and power factor. The voltage Vc is generated by the capacitor Co through the compensator 16. On the other hand, the main power supply 18 generates main power (Main power) with respect to the voltage Vc to supply power to the load 3.

Referring back to FIG. 1, while the electrical plug of the electronic device is connected to a power outlet, the switch S1 is not yet in a conducting state, and the power factor corrector 16 is not yet activated, while the conventional power supply 1 Operates in standby mode. In the standby mode of supplying power, the bleeder resistor 13 and the filter 12 of the conventional power supply 1 consume relatively more power, and in particular, the filter 12 comprising a resistor element and a capacitor element. Consumes very large power in standby mode. Therefore, the power consumption of the conventional power supply 1 in the standby mode does not meet the requirements of the International Energy Association (IEA), which must maintain the power consumption to be 0.1 W or less for each electric device.

SUMMARY OF THE INVENTION An object of the present invention is to provide a power supply apparatus which can effectively suppress a surge current and reduce power consumption in a standby mode, thereby obtaining a requirement of power saving.

A power supply according to a particular configuration of the present invention includes a switching unit, a bleeder resistor, a filter, a rectifier, a power factor corrector, an output capacitor, a rectifier diode, a surge absorber, a main power supply, and a standby power supply. Here, the switching unit receives AC power. The filter is connected to the switch via a bleeder resistor. As the switching unit is turned on, the filter filters the noise signal of the AC power. The rectifier connected to the filter receives the rectified AC power and outputs DC power. The power factor corrector connected to the rectifier receives the DC power and outputs a correction voltage. An output capacitor coupled to the power factor corrector receives the correction voltage. The positive terminal of the rectifying diode is connected to the AC power. A surge absorber is connected between the negative terminal of the rectifier diode and the output capacitor. The main power supply is connected to the output capacitor. The standby power supply is connected to the output capacitor.

Here, since the switching unit is cut off, AC power passes through the rectifier diode and the surge absorber to generate a standby voltage at the output capacitor, so the standby power supply generates a standby power, and the switching power is conducted while the AC power is conducted. Since the switching unit, the bleeder resistor, the filter, the rectifier, and the power factor corrector generate a switching voltage at the output capacitor, the main power supply can generate main power.

Power supply method of the present invention, the step of switching off the switching unit; Supplying AC power through the rectifier diode and the surge absorber to generate a standby voltage at the output capacitor; Controlling the switching unit to be turned on and to activate the power factor corrector; Delivering AC power to a power factor corrector through the switching unit, the bleeder resistor, the filter, and the rectifier; and generating a switching voltage at an output capacitor.

Therefore, through the above-described technical proposal of the present invention, the following effects are obtained. In the standby mode, by changing the circuit schematic design, the standby power consumption is reduced, so that the purpose of power saving is achieved. In the normal mode of power supply, the input current is low and the appropriate switching voltage level is accumulated faster, thereby achieving the purpose of "fast boot".

1 shows a block diagram of a power supply according to the prior art.
2 shows a circuit block diagram of an embodiment of a power supply according to the invention.
3A shows a flow diagram of an embodiment of a power supply according to a particular configuration of the present technology.
3B shows another flow diagram of an embodiment of a power supply according to a particular configuration of the present technology.
3C shows another flow diagram of an embodiment of a power supply according to a particular configuration of the present technology.

The above-described illustration and the following detailed description are examples for further explaining the configuration of the present invention. Other objects and advantages associated with the present invention are illustrated in the following description and the accompanying drawings.

2, a circuit block diagram of an embodiment of a power supply according to the present invention is shown. The power supply device 2 may be installed in an electronic device (not shown) to supply power to the load 4 of the electronic device. The electronic device may be a very thin TV monitor or another type of monitor. The load 4 may be an LED drive circuit.

Reference is made again to FIG. 2. When connecting the electrical plug of the electronic device to a power outlet, AC power, including surge current, is delivered to the power supply 2 of the embodiment according to the particular arrangement of the invention. Therefore, the power supply 2 effectively suppresses the surge current to effectively protect the end load 4 and supplies the standby power (STB power) to the load 4 in the standby mode. In addition, the power supply device 2 is controlled by the switching control signal Sin and the power factor correction control signal S _PFC to supply the main power to the load 4.

As shown in FIG. 2, the power supply 2 includes a switching unit S1, a bleeder resistor 21, a filter 22, a rectifier 24, a power factor corrector 26, an output capacitor Co, and a rectifier diode. (D1), surge absorber 20, main power supply 28, standby power supply 29. Here, the positive terminal of the rectifying diode D1 is connected to AC power. The surge absorber 20 is connected between the negative terminal of the rectifying diode D1 and the output capacitor Co. The standby power supply 29 is connected to the output capacitor Co.

In view of the above description, the surge absorber 20 may be a thermistor or negative temperature coefficient (NTC). The filter 22 may be an electromagnetic interference filter (EMI) or another type of filter capable of filtering a noise signal of AC power, for example a type II filter. Rectifier 24 may be a bridge rectifier or another type of rectifier capable of converting AC power to DC power.

When the electrical plug of the electronic device is connected to the power outlet as shown in FIG. 2, since the switching unit S1 is not yet conducting, AC power including a surge current can be transmitted to the power supply device 2. In addition, the surge current can be absorbed or suppressed by the surge absorber 20 inside the power supply 2 without damaging the end load 4.

In addition, since the electric plug of the electronic device is connected to the power outlet, and the switching unit S1 is not conducting yet, the electronic device is in the standby mode. AC power passes through rectifier diode D1 and surge absorber 20 to charge output capacitor Co up to the standby voltage at output capacitor Co. The standby power supply 29 generates standby power (STB power) according to the standby voltage of the output capacitor Co.

According to the embodiment described above, in the standby mode, the AC power is charged to the output capacitor Co through a charging path including the rectifying diode D1 and the surge absorber 20. Since the charging path does not include any high power consumption filter 22 and power factor corrector 26, the power supply 2 consumes less than 0.1W of standby power.

As shown in Fig. 2, the electrical plug of the electronic device is connected to the power outlet, the switching section S1 is turned on, and the power factor corrector 26 is activated, so that the electronic device is in the normal mode. AC power is charged to the output capacitor Co by the switching unit S1, the bleeder resistor 21, the filter 22, the rectifier 24, and the power factor corrector 26, and switches to the output capacitor Co. Accumulate voltage.

According to the embodiment described above, the filter 22 connected to the switching unit S1 through the bleeder resistor 21 filters the noise signal of AC power. Rectifier 24 connected to filter 22 receives the rectified AC power and outputs DC power. The power factor corrector 26 connected to the rectifier 24 and the output capacitor Co receives the DC power, outputs the correction voltage DC 'to further charge the output capacitor Co, and thus the switching voltage is output from the output capacitor Co. To charge. At the same time, the main power supply 28 generates main power based on the switching voltage of the output capacitor Co.

As shown in FIG. 2, in the situation where the standby voltage is maintained at the output capacitor Co, the switching unit S1 is controlled to be conducted by the switching control signal Sin, and the power factor corrector 26 is a power factor correction control signal. Managed to be activated by (S _PFC ), AC power is supplied to the output capacitor (Co) through the switching unit (S1), bleeder resistor (21), filter (22), rectifier (24) and power factor corrector (26). Since it can be charged, the voltage of the output capacitor Co can be boosted from the standby voltage to the switching voltage. Since the standby voltage is maintained at the output capacitor Co, the input current passing through the switching section S1, the bleeder resistor 21, the filter 22, the rectifier 24 and the power factor corrector 26 is relatively low. Therefore, since the switching voltage of the output capacitor Co accumulates very quickly, the output capacitor Co triggers the main power supply 28 to effectively generate main power, thereby increasing the boot speed of the electronic device. .

Compared with the conventional power supply 1, the power supply 2 of the embodiment obtains the following effects: In the standby mode, by changing the circuit schematic design, the standby power consumption is reduced, thereby achieving the purpose of power saving. Lose. In the normal mode of power supply, the input current is low and the proper switching voltage level accumulates faster, thus achieving the purpose of "fast boot".

Referring to FIG. 3A in conjunction with FIG. 2, a flow diagram of an embodiment of a power supply according to a particular configuration of the present technology is shown. The power supply method is applied such that standby power (STB power) is generated by the power supply device 2 described above. The switching section S1 is in a blocking state as shown in step S10. And, when the electrical plug of the electronic device is connected to the power outlet, AC power including the surge current is transferred to the power supply 2, and at the same time the surge current is absorbed and suppressed by the surge absorber 20. In addition, the AC power including the surge current may charge the output capacitor Co through the rectifying diode D1 and the surge absorber 20 in step S12, thereby providing a standby voltage to the output capacitor Co in step S14. Create As a result, according to the standby voltage, the standby power supply 29 generates standby power (STB power) in step S16.

Referring to FIG. 3B in conjunction with FIG. 2, another flow diagram of an embodiment of a power supply according to a particular configuration of the present technology is shown. The power supply method is applied such that main power is generated by the power supply 2 described above. The switching section S1 is controlled to be conductive, and the power factor corrector 26 is activated in step S11. Then, AC power is transferred to the power factor corrector 26 through the switching section S1, the bleeder resistor 21, the filter 22, the rectifier 24 in step S13. Since there is a standby voltage of the output capacitor Co, the current passing through the switching unit S1, the bleeder resistor 21, the filter 22, the rectifier 24 and the power factor corrector 26 is relatively low. Prevent unnecessary power consumption

Therefore, after the power factor corrector 26 is activated, the switching voltage of the output capacitor Co is generated in step S15. Since the standby voltage of the output capacitor Co already exists, the switching voltage can be obtained easily and quickly. As a result, according to the switching voltage, the main power supply 28 generates main power in step S17.

Referring to FIG. 3C in conjunction with FIG. 2, another flow diagram of an embodiment of a power supply according to a particular configuration of the present technology is shown. The power supply method is applied to terminate the generation of main power by the power supply 2 described above. The power factor corrector 26 ceases to function at step S20. At that time, the output capacitor Co still maintains the higher switching voltage in step S22, and the switching voltage of the output capacitor Co is utilized to cut off the AC power and by the rectifying diode D1 and the surge absorber 20. It is delivered to the output capacitor Co. In step S24, the switching unit S1 is cut off to terminate the supply of AC power to the power factor corrector 26 by the switching unit S1, the bleeder resistor 21, the filter 22, and the rectifier 24. . Therefore, the switching voltage of the output capacitor Co is reduced to the standby voltage. As a result, the main power supply 28 stops the generation of main power in step S26.

According to the embodiment described above, the following effects of the power supply device 2 proposed by the present invention are obtained: In the standby mode, by changing the circuit schematic design, the standby power consumption is reduced, whereby the purpose of power saving is achieved. Is achieved. In powering normal mode, the input current is low and the appropriate switching voltage level accumulates faster, thereby achieving the purpose of "fast boot".

Although the foregoing description describes only preferred embodiments of the present invention, the characteristics of the present invention are not limited thereto. All changes, substitutions or alterations easily contemplated by one skilled in the art are deemed to be within the scope of the invention as set forth in the following claims.

Claims (6)

A switching unit connected to the AC power;
A filter connected to the switching unit through a bleeder resistor and filtering a noise signal of the AC power while the switching unit is conductive;
A rectifier coupled to the filter, the rectifier receiving filtered AC power and outputting DC power;
A power factor corrector coupled to the rectifier for receiving the DC power and outputting a correction voltage;
An output capacitor coupled to the power factor corrector and receiving the correction voltage;
A rectifier diode having a positive terminal and a negative terminal, wherein the positive terminal is connected to the AC power;
A surge absorber coupled between the negative terminal of the rectifying diode and the output capacitor;
A main power supply connected to the output capacitor; And
A standby power supply connected to the output capacitor,
As the switching unit is cut off, AC power passes through the rectifier diode and the surge absorber to generate a standby voltage at the output capacitor, so the standby power supply generates a standby power, and the AC is turned on as the switching unit is turned on. And the main power supply generates main power as it passes through a resistor, filter, rectifier, and power factor corrector to produce a switching voltage at the output capacitor. The method according to claim 1,
The surge absorber is a thermistor and the standby power supply supplies standby power to the LED drive circuit. Blocking the switching unit;
Supplying AC power through the rectifier diode and the surge absorber to generate a standby voltage at the output capacitor;
Conducting the switching unit;
Delivering AC power to a power factor corrector through the switching unit, bleeder resistor, filter, and rectifier; and
Activating the power factor corrector to produce a switching voltage at the output capacitor. The method according to claim 3,
Generating a standby power by receiving a standby voltage using a standby power supply;
Generating main power by receiving the switching voltage using a main power supply;
Controlling the power factor corrector to be terminated while the switching unit is turned on;
Cutting off AC power delivered to the output capacitor through the rectifier diode and the surge absorber by utilizing the switching voltage in the output capacitor; And
Controlling the switching unit to shut off to prevent AC power from being transferred to the power factor corrector through the switching unit, the bleeder resistor, the filter, and the rectifier. The method of claim 4,
Further comprising terminating the main power supply from generating main power. The method of claim 4,
Wherein the surge absorber is a thermistor and the standby power supply supplies standby power to the LED drive circuit.

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