KR100975054B1 - Power sourcing apparatus and power source supplying method for driving of a power source reduction circuit - Google Patents

Abstract

Disclosed are a power supply device and a power supply method for driving a power saving circuit. In response to the driving request signal for the power saving circuit, the device outputs a low voltage to the power saving circuit, and a main power supply for controlling the supply of the main power according to a cutoff signal of the main power supply for driving the electronic device. And an overcurrent detector for detecting an overcurrent of the main power supply. Therefore, according to the present invention, when the power saving mode is requested in the electronic device, it is possible to cut off the main power and supply power only to the power saving circuit, thereby preventing power consumption and shortening the component life time of the electronic device. Instead of the switch, the main power is controlled by the on / off detection signal by the photo coupler to overcome the instability caused by the physical power control, and the overcurrent supplied to the electronic device can be detected to protect the circuit of the electronic device. Make sure

Description

Power sourcing apparatus and power source supplying method for driving of a power source reduction circuit

1 is a circuit diagram illustrating a power supply device for driving a power saving circuit according to the present invention provided on a secondary side of a switched mode power supply.

2 is a flowchart of an embodiment for describing a power supply method for driving a power saving circuit according to the present invention.

<Brief description of the major symbols in the drawings>

10: low voltage output unit 30: main power supply control unit

50: overcurrent detector

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a switching mode power supply (SMPS) provided in an electronic device such as a computer, a printer, a copier, or a multifunction device. More particularly, the present invention provides a switching device on a secondary side of a switching mode power supply. When the power saving mode is requested from the device, the main power is cut off and the power can be supplied only to the power saving circuit part, and the main power is controlled by the on / off detection signal by the photo coupler instead of the physical switch. The present invention relates to a power supply device and a power supply method for driving a power saving circuit for sensing an overcurrent supplied.

Switching mode power supply is a modular power supply that converts the power supplied from the outside into a power that can be accommodated by the electronics. The switching mode power supply uses a semiconductor switching characteristic to control the power supply by switching operation at a high frequency above a commercial frequency. .

The conventional switching mode power supply has a power rectification smoothing unit for making AC power to DC on the primary side of the transformer and a switching unit for controlling the switching operation, and smoothing and supplying the transformed power to DC on the secondary side of the transformer. It has a part. When AC power is applied to the input terminal, the switching mode power supply is converted into DC through a bridge diode and a capacitor of the rectifying smoothing part of the power supply. The converted direct current is switched through a pulse width modulation integrated circuit (PWM-IC) of the switching unit and applied to the secondary side of the transformer. The power applied by transforming through a transformer is again smoothed through a diode and a capacitor and outputted to an electronic device. Whether the power output to the electronic device is equal to or greater than the reference power in the feedback control unit, and is fed back to the switching unit provided on the primary side of the transformer, the switching operation is performed so that the output power is matched with the reference power.

On the other hand, the power saving circuit is a circuit implemented to drive only the minimum power (for example, timer driving, microprocessor driving, etc.) required by the electronic device when the electronic device is in the standby mode, not the operation mode.

However, the power saving circuit may or may not be provided in the electronic device. If the power saving circuit is not provided in the electronic device, since the user cannot select the power saving mode, there is a problem in that a lot of power is consumed even in the standby mode of the electronic device. If the power saving circuit is provided in the electronic device, there is a problem in that an output stage is provided by configuring a separate winding in addition to the winding of the main power supplied to the electronic device on the secondary side of the switching mode power supply. If a new output stage is configured to implement a power saving circuit, a diode and an electrolytic capacitor are also required for the output stage, and the winding of the transformer must be wound by the number of output stages, thereby increasing design difficulties. In addition, unless a separate output stage is provided, since the output power of the switching mode power supply is all transmitted to the electronic device, there is a problem in that a lot of power is consumed.

On the other hand, for example, the laser printer of the electronic device is to cut off the power by a physical switch when the power supply to the laser printer is required to be cut off by opening and closing of a cover, etc. It is possible to damage the in-switch, therefore, a conventional switching mode power supply causes a problem that a full power off cannot be expected due to damage of the physical switch.

In addition, there is a problem in that the electronic device can not be safely protected when an overcurrent flows to the secondary side of the conventional switching mode power supply.

The technical problem to be achieved by the present invention is to cut off the main power when the power saving mode is requested in the electronic device, to supply power only to the power saving circuit portion, and to control the main power by the on-off detection signal by the photo coupler. In addition, the present invention provides a power supply for driving a power saving circuit for sensing an overcurrent supplied to an electronic device.

Another object of the present invention is to provide a power supply method for driving a power saving circuit performed in a power supply device for driving the power saving circuit described above.

In order to achieve the above object, the power supply device for driving the power saving circuit according to the present invention in response to the drive request signal for the power saving circuit, the low voltage output unit for outputting a low voltage to the power saving circuit, the drive of the electronic device The main power supply control unit for controlling the supply of the main power and an overcurrent sensing unit for detecting an overcurrent of the main power according to the supply cutoff signal of the main power for the main power supply.

In order to achieve the above object, the power supply method for driving the power saving circuit according to the present invention is to determine whether the drive request signal for the power saving circuit or the supply cutoff signal of the main power for driving the electronic device is detected. If it is determined that the step, the drive request signal or the supply cutoff signal is detected, the step of interrupting the power supply of the main power and at the same time outputting a low voltage to the power saving circuit, if it is determined that the drive request signal or the supply cutoff signal is not detected, And supplying main power to the device.

Hereinafter, a power supply device for driving a power saving circuit according to the present invention will be described with reference to the accompanying drawings.

1 is a circuit diagram illustrating a power supply device for driving a power saving circuit according to the present invention provided on a secondary side of a switched mode power supply, and includes a low voltage output unit 10, a main power supply control unit 30, and an overcurrent detection unit ( 50).

The low voltage output unit 10 outputs a low voltage to the power saving circuit in response to the driving request signal for the power saving circuit (not shown). In response to the driving request signal for the power saving circuit, in order to output a low voltage to the power saving circuit, the low voltage output unit 10 includes a zener diode ZD, a first MOS field effect transistor FET 1, and resistors R1. And R2). A MOS field effect transistor is a single transistor made of MOS (Metal Oxide Semiconductor) technology, in which a conducting channel is insulated from a gate terminal by an oxide layer. Therefore, the MOS field effect transistor does not conduct even if a reverse voltage is applied to the gate. Morse field effect transistors can operate with less power. The drain terminal d of the first MOS field effect transistor FET 1 is connected to the output terminal of the transformer secondary side, the source terminal s is connected to one side of the resistors R1 and R2, and the gate terminal ( g) is connected to the input terminal IN2. In addition, the zener diode ZD is connected to the other side of the resistors R1 and R2.

The driving request signal for the power saving circuit is a signal provided by the central processing unit of the electronic device when the standby mode state is required for the electronic device. The driving request signal for the power saving circuit is input from the central processing unit of the electronic device to the gate terminal g of the first MOS field effect transistor FET 1 through the input terminal IN2. The first MOS field effect transistor FET 1 is switched on by the driving request signal for the power saving circuit input through the input terminal IN2, and the resistors R1 and R2 and the zener diode ZD are switched on. The low voltage generated by is output to the power saving circuit through the output terminal OUT3. The power saving circuit receives a low voltage from the low voltage output unit 10 to drive the power saving circuit. Therefore, the low voltage output unit 10 is provided at the output side of the transformer secondary side by one winding, so that the power saving circuit can be driven without the circuit configuration by the multiple windings, and the power consumption of the electronic device can be reduced.

The main power supply control unit 30 controls the supply of the main power according to the supply cutoff signal of the main power for driving the electronic device. In order to control the supply of the main power, the main power supply control unit 30 includes a second MOS field effect transistor FET 2. The source terminal s of the second MOS field effect transistor FET 2 is connected to the output terminal of the transformer secondary side, the gate terminal g is connected to the input terminal IN1, and the drain terminal d is the overcurrent sensing unit. It is connected to one side. The main power source refers to the power supply required for the electronic device in the operating mode. The supply cutoff signal to the electronic device of the main power supply is a signal for preventing the main power supply to the electronic device, and also a signal corresponding to the driving request signal of the power saving circuit described above. Therefore, the first MOS field effect transistor FET 1 of the low voltage output unit 10 and the second MOS field effect transistor FET 2 of the main power supply controller 30 are complementarily turned on and off. do. That is, when the second MOS field effect transistor FET 2 is turned off, the first MOS field effect transistor FET 1 is turned on, and when the second MOS field effect transistor FET 2 is turned on, the first MOS field effect transistor FET 2 is turned on. The MOS field effect transistor FET 1 is turned off. For example, the first MOS field effect transistor FET 1 uses an N-channel MOS field effect transistor, and the second MOS field effect transistor FET 2 uses a P-channel MOS field effect transistor to turn ON / OFF. Off-complementary action is taken. The supply cutoff signal to the electronic device of the main power supply is provided by the central processing unit of the electronic device and is input to the gate terminal g of the second MOS field effect transistor FET 2 through the input terminal IN1. In addition, as a result of the detection that the overcurrent flows to the main power in the overcurrent sensing unit, a cutoff signal of the main power is generated in the central processing unit of the electronic device and input to the main power supply controller. Also, for example, when an electronic device is a printer, when the supply of main power to the electronic device is required by opening and closing of the cover of the printer, the photo is used instead of the configuration in which the main power is cut off by a physical switch. It can also be configured to function as a supply cutoff signal of the main power supply by an on or off signal of a photo coupler. The photo coupler is an optical coupling element that combines a light emitting element and a light receiving element to form one element. As a result, the input side and the output side are electrically insulated, and a signal by light is transmitted. Therefore, by replacing the conventional physical switching element with the electronic switching element, it is possible to overcome the instability of the switching operation that can occur by the physical power supply control. When a main supply supply cutoff signal is applied to the second MOS field effect transistor FET 2 of the main power supply control unit 30, the second MOS field effect transistor FET 2 is turned off, and the electronic device is output through the output terminal OUT1. The supply of main power to the unit is cut off.

The overcurrent detector 50 detects overcurrent of the main power supply. In order to detect an overcurrent of the main power supply, the overcurrent detector 50 includes a comparator OP and a resistor R3. The resistor R3 is connected to the drain terminal d of the second MOS field effect transistor FET 2 corresponding to the main power supply controller 30. The comparator OP preferably uses an op amp. The comparator OP is located across both ends of the resistor R3 to detect whether the main power supply flowing through the output terminal OUT1 to the electronic device is overcurrent. The result detected by the comparator OP is supplied to the central processing unit of the electronic device through the output terminal OUT2. The central processing unit of the electronic device receives a detection result indicating that overcurrent flows to the main power from the comparator OP, generates a supply cutoff signal of the main power, and corresponds to the main power supply control unit 30 through the input terminal IN1. It transfers to the gate terminal g of the 2nd MOS field effect transistor FET2.

Hereinafter, a power supply method for driving a power saving circuit according to the present invention will be described with reference to the accompanying drawings.

2 is a flowchart illustrating an example of a power supply method for driving a power saving circuit according to the present invention, and outputs a low voltage to the power saving circuit according to whether a driving request signal or a supply cutoff signal is detected, Supplying main power to the device (steps 100 to 104).

First, it is determined whether the driving request signal for the power saving circuit or the supply cutoff signal of the main power for driving the electronic device is detected (step 100). The driving request signal for the power saving circuit is a signal provided by the central processing unit of the electronic device when the standby mode state is required for the electronic device. The main power supply cutoff signal for driving the electronic device is a signal for preventing the main power from being supplied to the electronic device and is a signal corresponding to the driving request signal of the power saving circuit. The driving request signal for the power saving circuit is detected by the low voltage output unit 10 as described above, and the supply cutoff signal of the main power supply for driving the electronic device is detected by the main power supply control unit 30 described above.

If it is determined that the driving request signal or the supply cutoff signal is detected, the power supply of the main power is cut off and a low voltage is output to the power saving circuit (step 102). When the driving request signal for the power saving circuit is detected, the first MOS field effect transistor FET 1 of the low voltage output unit 10 is turned on, and a low voltage is applied to the power saving circuit. At this time, the second MOS field effect transistor FET 2 of the main power supply control unit 30 is turned off to cut off the supply of main power provided to the electronic device. On the other hand, when the supply cutoff signal of the main power supply is detected by the over current or by the on / off of the photo coupler replacing the physical switch, the second MOS field effect transistor FET 2 of the main power supply control unit 30 It turns off and the supply of main power provided to an electronic device is interrupted | blocked. At this time, the first MOS field effect transistor FET 1 of the low voltage output unit 10 is turned on to apply a low voltage to the power saving circuit.

However, if it is determined that the driving request signal or the supply cutoff signal is not detected, main power is supplied to the electronic device (step 104). If the driving request signal or the supply cutoff signal is not detected, since the electronic device needs to be supplied with main power in the operation mode, the main power is supplied to the electronic device under the control of the main power supply control unit 30.

As described above, the power supply device and the power supply method for driving the power saving circuit according to the present invention can cut off the main power when the power saving mode is requested from the electronic device, and to supply power only to the power saving circuit. It can prevent the power consumption of the device and shorten the component life time, and also control the main power by the on / off detection signal by the photo coupler instead of the physical switch to overcome the instability that can occur due to the physical power control. There is an effect to protect the circuit of the electronic device by sensing the overcurrent supplied to the electronic device.

Claims (5)

A power supply for driving a power saving circuit included in a switching mode power supply for controlling power supply to an electronic device having a power saving circuit. A low voltage output unit configured to output a low voltage to the power saving circuit in response to a driving request signal for the power saving circuit; A main power supply control unit controlling the supply of the main power according to a supply cutoff signal of the main power for driving the electronic device; And An overcurrent detector for detecting an overcurrent of the main power source, And the driving request signal and the supply cutoff signal are signals based on a result of sensing an overcurrent of the main power supply. According to claim 1, wherein the power supply for driving the power saving circuit is The low voltage output unit is composed of a zener diode, a first MOS field effect transistor and resistors, the main power supply control unit is composed of a second MOS field effect transistor, and the overcurrent sensing unit is composed of a comparator and a resistor. Power supply for driving power saving circuits. The power supply apparatus of claim 2, wherein the power supply device for driving the power saving circuit is And the first MOS field effect transistor and the second MOS field effect transistor are complementarily turned on and off. The power supply apparatus of claim 3, wherein the power supply device for driving the power saving circuit is And a sensed result of the overcurrent detector is transmitted to the main power supply control unit as a supply cutoff signal of the main power supply. A power supply method for driving a power saving circuit performed in a switching mode power supply for controlling power supply to an electronic device having a power saving circuit, Determining whether a driving request signal for the power saving circuit or a supply cutoff signal of main power for driving the electronic device is detected; If it is determined that the driving request signal or the supply cutoff signal is detected, cutting off the power supply of the main power and simultaneously outputting a low voltage to the power saving circuit; And if it is determined that the driving request signal or the supply cutoff signal is not detected, supplying the main power to the electronic device. The driving request signal and the supply cutoff signal are signals based on a result of sensing an overcurrent of the main power supply.

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