KR20100024726A - Power supplier and method for saving standby power using the same - Google Patents

Abstract

PURPOSE: A power supply device and a method for reducing standby power using the same are provided to secure system stability by preventing a system error due to the difference between the charging and discharging timings and the set charging/discharging period of the back-up unit. CONSTITUTION: A power converter converts the AC power to the DC power. A microcomputer(205) generates a first control signal in a system standby mode. A back-up unit(207) supplies the power to a microcomputer in the system standby mode. A voltage sensor(210) generates a second control signal according to the voltage variation of the back-up unit. A switching unit(203) selectively controls the generation of the DC power of the power converter according to the first and second control signals.

Description

Power supply and standby power saving method using the same {POWER SUPPLIER AND METHOD FOR SAVING STANDBY POWER USING THE SAME}

The present invention relates to a power supply device, and more particularly, to a switching mode power supply device, a power supply device capable of minimizing power consumption in a standby state, and a standby power saving method using the same.

1 is a block diagram showing an embodiment of a power supply apparatus according to the prior art.

As shown in the figure, in the switching mode power supply according to the prior art, when AC power is input to the power supply, first, the rectification and the predetermined power are supplied to the DC power through the first rectification / smoothing unit 101. Smoothed. In addition, the DC power output from the first rectification / smoothing unit 101 is input to the transformer unit 102.

The transformer unit 102 generates an induced current by generating induction electromotive force by repeating supply and interruption of power output from the primary rectification / smoothing unit 101, thereby generating an induced current at the output side of the transformer unit 102. Accordingly, the voltage induced on the output side of the transformer 102 has a different level from the voltage on the input side, and according to the configuration of the transformer 102, various voltages having a plurality of levels required by the system are induced. can do.

At this time, the switching unit 103 is provided so that the supply and interruption of the power input to the transformer unit 102 is repeated. The switching unit 103 is configured to include a switching unit for supplying or cutting off power to the transformer unit 102, and a control unit for controlling the on / off of the switching unit.

The second rectifier / smoothing unit 104 is provided on the output side of the transformer unit 102. The second rectifier / smoothing unit 104 rectifies the voltage induced on the output side of the transformer unit 102 and smoothes the DC power of a constant level.

To this end, the second rectifying / smoothing unit 104 is provided with one or more rectifying / smoothing circuits to rectify and smooth the voltage of each level output from the transformer unit 102 to a DC voltage.

In this way, the power converted into direct current by the second rectifying / smoothing unit 104 supplies the necessary power to each load provided in the system.

At this time, any one of one or more levels of power supplied from the second rectifying / smoothing unit 104 is supplied to the microcomputer 105. The microcomputer 105 may be a central processing unit of an electronic device equipped with a power supply device according to the present invention as a control unit.

The microcomputer 105 accumulates the number of times of signal reception from the timer 106 and compares it with a set value, and controls the switching unit 103 to be repeatedly turned on or off or stopped according to the result. To this end, the timer 106 generates a signal at a constant rate and transmits the signal to the microcomputer 105.

On the other hand, the operation of the switching unit 103 is stopped and no induced voltage is generated on the output side of the transformer unit 102. Accordingly, the microcomputer 105 supplies power from the second rectifying / smoothing unit 104. The backup unit may be configured to preserve the data of the microcomputer 105 and to supply power to the microcomputer 105 to enable wake-up from the standby mode to the operation mode when the supply is not available. 107 is provided.

The backup unit 107 is charged with power by any one of the power supplied from the second rectifying / smoothing unit 104. The power charged in the backup unit 107 is supplied to the microcomputer 105 when no other power is supplied to the microcomputer 105.

Meanwhile, any one of the power supplied from the second rectifying / smoothing unit 104 is received by the first feedback unit 108, and the first feedback unit 108 is currently present in the transformer unit 102 and the first unit. The secondary rectifier / smoothing unit 104 generates a signal indicating whether power is supplied to the system and transmits the signal to the switching unit 103.

In addition, the second feedback unit 109 connected to the microcomputer 105 transmits an on / off signal of the switching unit included in the switching unit 103 to the switching unit 103 according to the command of the microcomputer 105. do.

The microcomputer 105 monitors the power consumption of the load side, and when the power consumption of the load side is not large, through the second feedback unit 109 to slow down the on / off duty ratio of the switching unit 103. The switching unit 103 is controlled, and when the power consumption of the load side is high, the on / off duty ratio of the switching unit 103 is increased. ) Stops the on / off of the switching unit 103.

That is, the microcomputer 105 stops the on / off of the switching unit 103 in the system standby mode. However, the microcomputer 105 has a time value for charging the backup unit 107 and time information for discharging the backup unit 107 as a preset value and is received from the timer 106. By comparing the time counted by the signal with the set values, if the backup unit 107 needs to be charged, the power is supplied to the backup unit 107 by repeating the on / off of the switching unit 103. When the backup unit 107 is fully charged, the switching unit 103 stops repeating on / off.

However, such a power supply device determines whether to switch by counting a certain time and period using a timer and comparing it with a set value, so that the capacity of the backup unit and its charging and discharging time should be measured and set in advance. There was a hassle.

In addition, since the load amount in the standby mode is different for each system equipped with a power supply device, there is a difference in the discharge time of the backup unit according to this, there was a problem that must be set differently for each system.

In addition, since the charging time and the discharge time of the backup part are estimated and the charging and discharging of the backup part is controlled accordingly, an error may occur.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to back up at an appropriate timing in the system standby mode even if the capacity of the backup unit and the charging and discharging times thereof are not measured and set in advance. The present invention provides a power supply device capable of performing negative charging and discharging and a standby power saving method using the same.

Another object of the present invention is to provide a power supply device and a standby power saving method using the same, which can be applied to various systems each having different loads in the standby mode without a separate setting according to each system characteristic.

It is still another object of the present invention to provide a power supply device capable of preventing a system error due to an error between a charging / discharging cycle set during the charging / discharging control of a backup unit and an actual charging / discharging timing of the backup unit, and a standby power saving method using the same. .

According to a feature of the present invention for achieving the above object, the present invention comprises: a power conversion unit for receiving at least one DC power to generate at least one DC power supply to supply to the load side; A microcomputer for generating a first control signal according to whether the system enters the standby mode; A backup unit which receives DC power from the power converter and charges the power and supplies power to the microcomputer when the system enters the standby mode; A voltage sensing unit sensing a voltage of the backup unit to generate a second control signal according to a change in voltage of the backup unit; And a switching unit for selectively controlling whether to generate DC power of the power conversion unit according to the first control signal and the second control signal.

The switching unit may include: a control unit configured to receive the first control signal and the second control signal and determine whether to stop generation of DC power of the power conversion unit; And a switching unit for selectively stopping power generation of the power conversion unit according to a command of the control unit.

In this case, the first control signal is composed of a signal indicating a system normal operation mode and a standby mode signal, and the second control signal includes at least two distinct signals; When the voltage of the backup unit decreases below the predetermined minimum threshold voltage and when the voltage of the backup unit rises above the preset maximum threshold voltage, the signals may be switched to different signals.

And the minimum threshold voltage is set to a value corresponding to a minimum voltage value of the backup unit which enables the backup unit to supply power for driving the microcomputer in a system standby mode. The maximum threshold voltage may be set to a value corresponding to a voltage value of the backup unit to determine whether the backup unit is fully charged.

In addition, the power conversion unit, a transformer for converting the voltage of the input power to one or more voltage values required for the system load side; And it may be configured to include a rectifying / smoothing unit for rectifying and smoothing the power output from the transformer to convert to DC power.

The microcomputer may be a central processing unit that controls the overall operation of the system.

The control unit may selectively stop generating DC power of the power conversion unit when it is detected that the system is in the standby mode by the first control signal.

The control unit may be further configured to resume generation of the DC power of the power conversion unit when it is detected that the voltage of the backup unit decreases below the minimum threshold voltage by the second control signal in a system standby mode. When it is detected that the voltage of the backup unit increases above the maximum threshold voltage, the switching unit may be controlled to stop generation of the DC power of the power conversion unit.

The power supply device may further include one or more switches generated by the power conversion unit to selectively block each DC power supplied to each load of the system.

In this case, when entering the system standby mode, the microcomputer may turn off the remaining switches except for the switch connected to the DC power supplied to the backup unit.

On the other hand, the present invention, by receiving an external power source to generate at least one or more DC power supply to the load side, the microcomputer to control the overall operation of the system, and the DC power supplied from the power conversion unit And a backup unit for supplying power to the microcomputer when the system enters the standby mode, the method comprising: (A) detecting entering the system standby mode; (B) stopping generation of the DC power of the power conversion unit when entering the system standby mode; (C) detecting a voltage of the backup unit; (D) repeating the resumption and interruption of the generation of the DC power of the power conversion unit according to the voltage change of the backup unit.

Wherein (D), if it is detected that the voltage of the backup unit decreases below a predetermined minimum threshold voltage, the step of restarting the DC power generation of the power conversion unit; And when the voltage of the backup unit is detected to increase above a predetermined maximum threshold voltage, stopping the generation of the DC power of the power converter.

At this time, the minimum threshold voltage is set to a value corresponding to the minimum voltage value of the backup unit to enable the backup unit to supply power for driving the microcomputer in the system standby mode; The maximum threshold voltage may be set to a value corresponding to a voltage value of the backup unit to determine whether the backup unit is fully charged.

In addition, the standby power saving method may further include (E) opening a power supply supplied to the load side from the power converter except for the DC power supplied to the backup unit when entering the system standby mode.

The standby power saving method includes: (F) detecting a return from the standby mode to the system normal operation mode; (G) resuming DC power generation of the power conversion unit; And (H) shorting the power connection supplied from the power converter to the load side.

As described in detail above, according to the power supply device and the standby power saving method using the same according to the present invention, the following effects can be expected.

That is, even if the capacity of the backup unit, its charging time and discharge time, etc. are not measured and set in advance, charging and discharging of the backup unit can be performed at an appropriate timing in the system standby mode, which does not require a repeated measurement process.

In addition, according to the power supply device and the standby power saving method using the same according to the present invention, there is an advantage that the load can be directly applied to various systems having different loads in the standby mode without a separate setting according to each system characteristic.

In addition, according to the power supply apparatus and the standby power saving method using the same according to the present invention, system stability is ensured because an error between the charge / discharge period set during the charge / discharge control of the backup unit and the error between the charge and discharge timing of the backup unit can be prevented. It has the advantage of being.

Hereinafter, with reference to the accompanying drawings a specific embodiment of the power supply apparatus according to the present invention as described above will be described in detail.

2 is a block diagram showing a schematic configuration of a power supply apparatus according to a specific embodiment of the present invention.

As shown in FIG. 2, when AC power is input to the power supply device according to the present invention, the AC power is rectified and smoothed to a DC power of a predetermined level via the first rectifying / smoothing unit 201. In addition, the DC power output from the first rectification / smoothing unit 201 is input to the transformer unit 202.

The transformer 202 generates induction current by generating induction electromotive force by repeating supply and interruption of power output from the primary rectification / smoothing unit 201 to generate an induction current at the output side of the transformer 202. Accordingly, the voltage induced at the output side of the transformer unit 202 has a different level from the voltage at the input side, and according to the configuration of the transformer unit 202, various voltages having a plurality of levels necessary for the system are induced. can do.

At this time, the switching unit 203 is provided to repeat the supply and interruption of the power input to the transformer unit 202. The switching unit 203 includes a switching unit for supplying or cutting off power to the transformer unit 202, and a control unit for controlling on / off of the switching unit.

The second rectifier / smooth unit 204 is provided on the output side of the transformer unit 202. The second rectifier / smoothing unit 204 rectifies the voltage induced on the output side of the transformer unit 202 to smooth the DC power of a constant level.

To this end, the second rectifying / smoothing unit 204 is provided with one or more rectifying / smoothing circuits to rectify the voltage of each level output from the transformer unit 202 into a DC voltage necessary for the load side provided in the system. And smooth.

In this way, the power converted into direct current by the second rectifying / smoothing unit 204 supplies power required for each load included in the system. The power supplied to each load provided in the system may be a plurality of voltage values Vo1 to Von as described above, so that the transformer 202 and the second rectifier / smooth unit 204 Transformer, rectify and smooth the DC power supply according to the voltage value required for each load.

At this time, any one of one or more levels of power supplied from the second rectifying / smoothing unit 204 is supplied to the microcomputer 205. The microcomputer 205 may be a central processing unit of an electronic device equipped with a power supply device according to the present invention as a control unit.

The microcomputer 205 monitors the amount of power consumed by the load side of the system, and monitors whether the system enters the standby mode and the normal operation mode by executing an operating system of the system provided with the power supply device according to the present invention. .

When the system enters the standby mode, the operation of the switching unit 203 is stopped to stop the generation of the induced voltage on the output side of the transformer unit 202, and from the second rectifying / smoothing unit 204, Shut off the power supply to the load side.

On the other hand, the operation of the switching unit 203 is stopped and no induced voltage is generated on the output side of the transformer unit 202. Accordingly, the microcomputer 205 supplies power from the second rectifying / smoothing unit 204. The backup unit may be configured to preserve the data of the microcomputer 205 and to supply power to the microcomputer 205 to enable wake-up from the standby mode to the operation mode when the supply is not available. 207 is provided.

The backup unit 207 is charged by any one of the power supplied from the second rectification / smoothing unit 204 when the on / off of the switching unit 203 is repeated. The power charged in the backup unit 207 is supplied to the microcomputer 205 when the operation of the switching unit 203 is stopped and no other power is supplied to the microcomputer 205.

However, in the system standby mode, only the power supplied from the second rectifying / smoothing unit 204 to the backup unit 207 is supplied and the remaining load side is not supplied with power. Switches may be provided at the output terminals of the 204, respectively. That is, in the system standby mode, the switches provided at the respective output terminals may be turned off so that power is not supplied to the remaining output terminals except for the Vo2 terminal for charging the backup unit 207 among the Vo1 to Von shown in the drawing.

At this time, since the backup unit 207 supplies power to the microcomputer 205 in the standby mode, the voltage value of the power charged in the backup unit 207 continuously decreases as time passes after entering the standby mode. . Therefore, even in a system standby state, the process of resuming the switching unit 203 and recharging the backup unit 207 is repeatedly performed before all of the power charged in the backup unit 207 is exhausted. That is, in the system standby state, the backup unit 207 is repeatedly charged and discharged power.

On the other hand, any one of the power supplied from the second rectifying / smoothing unit 204 is received by the first feedback unit 208, the first feedback unit 208 is currently the transformer 202 and the first The secondary rectification / smoothing unit 204 generates a signal indicating whether power is supplied to the system and transmits the signal to the switching unit 203.

The control unit included in the switching unit 203 receives a signal from the first feedback unit 208 and controls the on / off of the switching unit included in the switching unit 203.

In addition, a second feedback unit 209 is connected to the microcomputer 205. The second feedback unit 209 is provided between the microcomputer 205 and the control unit provided in the switching unit 203.

The microcomputer 205 enters the standby mode of the system by monitoring the amount of power consumed at the load side of the system equipped with the power supply according to the present invention and executing the operating system of the system equipped with the power supply according to the present invention. Whether the system enters the standby mode and monitors whether the system enters the standby mode, a signal is transmitted to the second feedback unit 209 so that the switching operation of the switching unit 203 can be stopped.

On the other hand, when the system is switched back to the normal operation mode, the corresponding signal is transmitted to the second feedback unit 209 so that the operation of the switching unit 203 can be resumed.

In addition, the power supply device according to the present invention detects the voltage of the power charged in the backup unit 207 for supplying power to the microcomputer 205 in the system standby mode and generates a signal by comparing with a preset threshold voltage. The sensing unit 210 is provided.

Since the backup unit 207 supplies power to the microcomputer 205 in the standby mode, the voltage value of the power charged in the backup unit 207 continuously decreases as time passes after entering the standby mode. Therefore, the voltage detector 210 senses the voltage of the backup unit 207 and compares it with the minimum threshold voltage.

The minimum threshold voltage is such that the backup unit 207 can be recharged before the voltage value is reduced such that the backup unit 207 cannot sufficiently supply power consumed by the microcomputer 205 in a system standby state. The appropriate voltage value is selected.

That is, the voltage sensing unit 210 measures the voltage value of the backup unit 207 and compares it with the minimum threshold voltage, and if the voltage value of the backup unit 207 is less than or equal to the minimum threshold voltage, it corresponds to this. The signal is transmitted to the second feedback unit 209.

The second feedback unit 209 receives such a signal from the voltage sensing unit 210 and transmits a signal for controlling the operation of the switching unit 203 to the switching unit 203.

In addition, when the voltage detecting unit 210 detects that the voltage value of the backup unit 207 is less than or equal to the minimum threshold voltage and resumes the operation of the switching unit 203, charging of the backup unit 207 is resumed. The voltage value of the backup unit 207 is compared with a predetermined maximum threshold voltage. At this time, the highest threshold voltage is set approximately to the voltage value when the backup unit 207 is fully charged.

When the voltage value of the backup unit 207 is detected as greater than or equal to the highest threshold voltage, the voltage detector 210 transmits a corresponding signal to the second feedback unit 209 to switch the switching unit 203. Allow operation to stop.

In more detail, the microcomputer 205 transmits a low signal to the second feedback unit 209 while the system is in a normal operation and a high signal in a system standby state.

When the voltage detector 210 detects that the voltage value of the backup unit 207 decreases below the minimum threshold voltage, the voltage detector 210 generates a low signal, and the voltage value of the backup unit 207 gradually increases to the highest value. High signal is generated when the threshold voltage is reached.

The second feedback unit 209 receives both the signal from the microcomputer 205 and the signal from the voltage sensing unit 210 so that the switching unit 203 only when both signals are high level signals. ) Is stopped.

That is, the power supply to the system is cut off by stopping the operation of the switching unit 203 only when the system enters the standby state and the voltage value of the backup unit 207 is greater than or equal to the maximum threshold voltage.

In this way, the power charged to the backup unit 207 is supplied to the microcomputer 205 while the power supply to the system is cut off. When it is detected that the voltage value of the backup unit 207 is less than or equal to the minimum threshold voltage, the signal output from the voltage detector 210 is converted into a low signal to operate the switching unit 203 to operate the backup unit 207. ) To be charged.

In this case, the second feedback unit 209 may include an AND gate 211 to generate another control signal only when both signals are at a high level.

The operation of the switching unit 203 according to the signal generated as described above is summarized as follows.

Microcomputer output (V1) Voltage detector output (V2) AND GATE output (V3) Switching unit operation Low Low Low action High Low Low action Low High Low action High High High stop

Hereinafter, a standby power saving method using the power supply apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

3 and 4 are flowcharts illustrating a standby power saving method step by step according to a specific embodiment of the present invention, Figure 5 is a standby mode in the power supply and standby power saving method according to a specific embodiment of the present invention. It is a graph showing the change in the control signal and the change in power output accordingly.

As shown in FIG. 3, the standby power saving method according to the present invention starts from step S10 in which the switching unit 203 operates when the system is turned on. The operation of the switching unit 203 in the tenth step S10 means that the switching unit included in the switching unit 203 repeats on / off.

When the on / off of the switching unit included in the switching unit 203 is repeated as described above, an induced electromotive force is generated to induce a voltage on the output side of the transformer unit 202. At this time, the voltage induced on the output side of the transformer 202 has one or more voltage levels converted according to the design of the transformer 202.

In this way, the power output by the transformer 202 is supplied to the load side of the system (S11).

Meanwhile, as the switching unit 203 operates as described above, the microcomputer 205 continuously monitors whether the system standby mode entry condition is completed in the normal operation state in which driving power is supplied to the load side of the system (S20). ).

The standby mode entry condition may correspond to a case in which a new command input to the system is not detected for a predetermined time or when the user directly enters the standby mode enter command.

The microcomputer 205 may check whether the system enters the standby mode by executing a system operating system controlling the normal operation mode and the standby mode of the system.

When it is detected that the system enters the standby mode in the twentieth step (S20), the switching operation of the switching unit 203 is stopped (S21). The twenty-first step S21 detects that the microcomputer 205 enters the standby mode of the system and notifies this to the control unit included in the switching unit 203 according to a signal determined by the microcontroller. The operation of the switching unit included in the switching unit 203 is stopped.

As the operation of the switching unit 203 is stopped in the twenty-first step, the voltage is not induced on the output side of the transformer unit 202 (S22). This also shuts off power to each load side of the system.

As described above, the voltage sensing unit 210 continuously monitors the voltage of the backup unit 207 while the operation of the switching unit 203 is stopped and the power supply is stopped. As a result, when it is determined that the backup unit 207 is completely discharged (S30), the switching operation of the switching unit 203 is resumed (S31).

At this time, in the thirtieth step (S30), the voltage of the backup unit 207 is compared with a predetermined minimum threshold voltage, and when it is less than the minimum threshold voltage, it is determined that the backup unit 207 is fully discharged.

On the other hand, as the switching operation of the switching unit 203 is resumed in step 31 (S31), the voltage is again induced on the output side of the transformer unit 202, and accordingly the voltage connected to the output side of the transformer unit 202 Charging of the backup unit 207 is resumed (S32).

In this state, when the on / off of the switching unit 203 is repeated and the charging of the backup unit 207 proceeds, the voltage sensing unit 210 has a maximum threshold value at which the voltage of the backup unit 207 is preset. Detect whether or not the voltage is reached.

When the voltage of the backup unit 207 reaches a predetermined maximum threshold voltage, the voltage detector 210 determines that the backup unit 207 is fully charged (S40).

Accordingly, the voltage sensing unit 210 transmits a signal to the switching unit 203 so that the switching operation of the switching unit 203 is stopped. Accordingly, the process is repeated from the twenty-first step.

On the other hand, if it is determined that the backup unit 207 is completely discharged in the thirtieth step, the voltage detection unit 210 may perform the backup unit until the voltage of the backup unit 207 reaches the minimum threshold voltage. 207 continuously senses the voltage.

At this time, the microcomputer 205 continuously detects whether the system returns to the normal operation mode (S50), and if the return to the operation mode is detected, the following steps are repeated from the tenth step.

On the other hand, if it is determined in step 40 that the backup unit 207 is not fully charged, the voltage detection unit 210 may perform the backup unit until the voltage of the backup unit 207 reaches the maximum threshold voltage. The voltage of 207 is continuously sensed.

In this case, when it is detected that the system returns to the normal operation mode (S60), the microcomputer 205 performs the following steps step by step from the tenth step.

As shown in FIG. 4, a standby power saving method according to a specific embodiment of the present invention is illustrated step by step based on a signal generated for controlling the switching operation of the switching unit 203.

As shown in FIG. 4, the voltage output from the microcomputer 205 (hereinafter referred to as 'V1') and the voltage output from the voltage sensing unit 210 in a state where the power of the system is turned on to start driving the system. (Hereinafter referred to as 'V2') are all started at the low level (S100).

If both V1 and V2 transmit a low level signal as described above, the switching unit 203 is repeated on and off (S110). Accordingly, each load side of the system is supplied with power from the output side of the transformer unit 202.

At this time, the output of the transformer 202 is charged by receiving the power of the backup unit 207 connected to the rectified / smoothed power.

When the backup unit 207 is fully charged and the voltage of the backup unit 207 reaches the maximum threshold voltage (S120), the voltage detection unit 210 detects this and sends a high level signal to the second feedback circuit. Transmission to the switching unit 203 via the unit 209.

Accordingly, the voltage V1 is output at the low level and the voltage V2 is at the high level (S200).

Meanwhile, the microcomputer 205 continuously monitors the power mode of the system. When the power mode of the system is changed from the normal operation mode to the standby mode (S210), the microcomputer 205 detects this and converts the voltage V1 output from the low level to the high level voltage. To print.

Accordingly, when both the voltage V1 and the voltage V2 are output at a high level (S300), the switching operation of the switching unit 203 is stopped (S310).

When the switching operation of the switching unit 203 is stopped, since the power is not output from the transformer unit 202, the power supply to the backup unit 207 is also stopped. Accordingly, the backup unit 207 is not charged, and the power charged in the backup unit 207 is supplied to the microcomputer 205, so that the voltage of the backup unit 207 decreases with time. Done.

At this time, the voltage detecting unit 210 monitors whether the voltage of the backup unit 207 falls below the minimum threshold voltage, and when the voltage of the backup unit 207 decreases below the backup unit 207, It is determined that the complete discharge (S320).

However, if it is determined that the backup unit 207 is completely discharged in step 320 (S320), the voltage detection unit 210 until the voltage value of the backup unit 207 reaches the minimum threshold voltage. The voltage of the backup unit 207 is continuously monitored.

On the other hand, if it is determined in step 320 that the backup unit 207 is completely discharged, the voltage detector 210 generates a Low signal. That is, the voltage V1 is output at high level and the voltage V2 is output at low level (S400).

Accordingly, the on / off repeat operation of the switching unit 203 is resumed (S410). That is, the control unit included in the switching unit 203 receives signals from the microcomputer 205 and the voltage sensing unit 210 and accordingly turns on / off the switching unit included in the switching unit 203. Repeat.

As the operation of the switching unit 203 is resumed in operation 410 (S410), power is also induced to the output side of the transformer unit 202, and charging of the backup unit 207 is resumed.

The voltage detecting unit 210 monitors the change of the voltage of the backup unit 207 again and determines that the backup unit 207 is fully charged when the voltage of the backup unit 207 reaches the maximum threshold voltage. The process from step 300 is repeated.

In this process, however, the microcomputer 205 continuously monitors whether the power mode of the system is switched, and when the return to the normal operation mode is detected (S500 and S600), the process from the step 100 is repeated again.

At this time, the return to the system normal operation mode is detected by the user's input or by the user directly inputting a return command to the normal operation mode.

Meanwhile, in the standby power saving method according to the present invention as described above, changes in control signals for repeating or stopping the on / off operation of the switching unit 203 and changes in the output of the transformer 202 accordingly are specifically described. Looking at it as shown in FIG.

First, the signal of the microcomputer 205 is output at the low level in the normal operation mode, and is switched to the high level signal when the entry into the standby mode is detected. When entering the normal operation mode again, the microcomputer 205 outputs a low level signal.

On the other hand, the signal of the voltage sensing unit 210 is initially output to the low level when the system is turned on, but if the backup unit 207 is fully charged, that is, if the voltage of the backup unit 207 is greater than the maximum threshold voltage, The high level is switched.

When the voltage of the backup unit 207 decreases again, the same signal is output, and when it is detected that the voltage of the backup unit 207 decreases below the minimum threshold voltage, the signal is switched to low level. .

That is, when it is detected that the voltage value of the backup unit 207 rises above the maximum threshold voltage, the signal is converted into a high level signal, and when it is detected that the voltage value of the backup unit 207 falls below the minimum threshold voltage, it is converted to a low level signal.

On the other hand, the switching unit 203 receives the signal V1 from the microcomputer 203 and the signal V2 from the voltage sensing unit 210 and the switching only when the voltage V1 and the voltage V2 are both at a high level. The on / off operation of the unit 203 is stopped, and in other cases, the on / off operation of the switching unit 203 is repeated.

Accordingly, the output from the transformer 202 becomes 0 only in a section in which both the voltage V1 and the voltage V2 are high level, and the voltage Vo (FIG. 2) as designed to be transmitted to each load in other sections. Eso Vo1 to Von).

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

1 is a block diagram showing an embodiment of a power supply according to the prior art.

2 is a block diagram showing a schematic configuration of a power supply apparatus according to a specific embodiment of the present invention.

3 and 4 is a flow chart illustrating a step-by-step method for reducing standby power according to a specific embodiment of the present invention.

5 is a graph illustrating a change in a control signal and a change in power output according to a standby mode in a power supply device and a standby power saving method according to a specific embodiment of the present invention.

** Description of the symbols for the main parts of the drawings **

201: primary rectifying and smoothing unit 202: transformer unit

203: switching unit 204: second rectifying / smoothing unit

205: micom 207: backup unit

208: first feedback part 209: second feedback part

210: voltage detector 211: end gate

Claims (16)

A power converter configured to receive external power and generate at least one DC power to supply the load to the load; A microcomputer for generating a first control signal according to whether the system enters the standby mode; A backup unit which receives DC power from the power converter and charges the power and supplies power to the microcomputer when the system enters the standby mode; A voltage sensing unit sensing a voltage of the backup unit to generate a second control signal according to a change in voltage of the backup unit; And And a switching unit for selectively controlling whether to generate DC power of the power conversion unit according to the first control signal and the second control signal. The method of claim 1, The switching unit, A control unit configured to receive the first control signal and the second control signal and determine whether to stop the generation of the DC power of the power conversion unit; And And a switching unit for selectively stopping power generation of the power conversion unit according to the command of the control unit. The method of claim 2, The first control signal, A power supply comprising a signal indicating the system normal operation mode and a standby mode signal. The method of claim 2, The second control signal, At least two distinct signals; And when the voltage of the backup unit decreases below a predetermined minimum threshold voltage and when the voltage of the backup unit rises above a predetermined maximum threshold voltage, the power supply apparatus changes to a different signal. The method of claim 4, wherein The minimum threshold voltage is, The backup unit is set to a value corresponding to a minimum voltage value of the backup unit that enables the backup unit to supply power for driving the microcomputer in the system standby mode; The highest threshold voltage is, And a value corresponding to a voltage value of the backup unit to determine whether the backup unit is fully charged. The method according to claim 1 or 2, The power conversion unit, A transformer for converting the voltage of the input power to one or more voltage values required at the system load side; And And a rectification / smoothing unit for rectifying and smoothing the power output from the transformer unit and converting the power to a DC power source. The method according to claim 1 or 2, The microcomputer, Power supply, characterized in that the central processing unit (Central Processing Unit) that controls the overall operation of the system. The method of claim 4, wherein The control unit, And detecting the generation of the DC power of the power conversion unit selectively when it is detected that the system is in the standby mode by the first control signal. The method of claim 8, The control unit, In response to the second control signal detecting that the voltage of the backup unit decreases below the minimum threshold voltage in a system standby mode, restarting generation of DC power of the power conversion unit; And controlling the switching unit to stop the generation of the DC power of the power converter when the voltage of the backup unit is detected to increase above the maximum threshold voltage. The method according to claim 1 or 2, The power supply device, And at least one switch generated by the power conversion unit to selectively block each DC power supplied to each load of the system. The method of claim 10, The microcomputer, When the system enters the standby mode, the power supply device characterized in that the switch off except for the switch connected to the DC power supplied to the backup unit. A system standby mode is charged by a power converter that generates external power and generates at least one DC power and supplies it to a load, a microcomputer that controls the overall operation of the system, and a DC power supplied from the power converter. In the power supply device comprising a backup unit for supplying power to the microcomputer when entering, (A) detecting a system standby mode entry; (B) stopping generation of the DC power of the power conversion unit when entering the system standby mode; (C) detecting a voltage of the backup unit; (D) the standby power saving method, characterized in that the step of repeating the restarting and interruption of the generation of the DC power of the power conversion unit according to the voltage change of the backup unit. The method of claim 12, Step (D), Resuming the generation of the DC power of the power conversion unit when it is detected that the voltage of the backup unit decreases below a predetermined minimum threshold voltage; And And stopping the generation of the DC power of the power conversion unit when it is detected that the voltage of the backup unit increases above a preset maximum threshold voltage. The method of claim 13, The minimum threshold voltage is, The backup unit is set to a value corresponding to a minimum voltage value of the backup unit that enables the backup unit to supply power for driving the microcomputer in the system standby mode; The highest threshold voltage is, Standby power saving method characterized in that it is set to a value corresponding to the voltage value of the backup unit to determine whether the backup unit is fully charged. The method of claim 13, The standby power saving method, (E) the standby power saving method further comprises the step of opening the power supply supplied to the load side from the power conversion unit except for the DC power supplied to the backup unit when entering the system standby mode. The method of claim 13, The standby power saving method, (F) detecting a return from the standby mode to the system normal operation mode; (G) resuming DC power generation of the power conversion unit; And (H) a standby power saving method, characterized in that it further comprises the step of shorting the power connection supplied from the power converter to the load side.

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