KR20020071215A - Prevent power latching circuit of the switching mode power supply - Google Patents

Abstract

PURPOSE: A circuit for preventing power latch of a switching mode power supply is provided to improve the re-starting procedure of a power supply by preventing the decrease of feedback control signal. CONSTITUTION: A power controller(21) controls power of a load(25). A power transistor(22) turns-on/off, in response to an output signal of the power controller(21). A transformer(23) receives an output signal of the power transistor(22) and transforms an AC(Alternating Current) voltage of a primary winding to send it to a secondary winding. An off-time control unit(26) detects the voltage to control an off-time of the power controller(21). A rectifying/smoothing unit(24) receives an AC voltage from the transformer(23) to make it to a DC(Direct Current) voltage. A secondary voltage detecting unit(27) compares the DC voltage of the rectifying/smoothing unit(24) with a reference voltage. A feedback unit(28) feedbacks a difference between the detected voltage of the secondary voltage detecting unit(27) and the reference voltage. An on-time control unit(29) receives an output signal of the feedback unit(28) to control an on-time. An on-time detecting unit(30) transfers the detected signal to the on-time control unit(29). A power control unit(31) receives the signal detected from the on-time detecting unit(30) to stabilize the power of the power controller(21).

Description

Power latch prevention circuit of switching mode power supply {PREVENT POWER LATCHING CIRCUIT OF THE SWITCHING MODE POWER SUPPLY}

The present invention relates to a power latch prevention circuit, and in particular, a control signal fed back when the secondary load current decreases is reduced, so that the switching mode power supply cannot be controlled and thus becomes a power latch mode. It relates to a prevention circuit.

FIG. 1 is a conventional switching mode power supply control block. As shown therein, a power controller 11 for controlling power of a load 15 and an output signal of the power controller 11 are shown. A power transistor 12 that operates on / off by receiving an input, a transformer 13 that receives an output signal of the power transistor 12, transforms a primary AC voltage, and transmits the secondary voltage to a secondary side, and the power transistor 12. ) Detects the voltage transmitted through the transformer 13 during the off operation, and controls the off time of the power controller 11, and receives an output alternating current from the transformer 13 to a direct current. The rectifying / smoothing section 14 to be made, the secondary voltage detecting section 17 for comparing the DC voltage detected by the rectifying / smoothing section 14 and the reference voltage, and the detected voltage with the secondary voltage detecting section 17. Feedback that feeds back the difference in reference voltage The unit 18 and the on-time control unit 19 for receiving the output signal of the feedback unit 18 to control the on-time time.

In the switching mode power supply control block diagram configured as described above, when the ON operation signal output from the power controller 11 is applied to the power transistor 12, the AC voltage is converted by the ON operation of the power transistor 12. 13 through the rectification / smoothing unit 14 through the direct current is delivered to the secondary voltage detection unit 17 and the load 15. The voltage difference between the voltage detected by the secondary voltage detector 17 and the reference voltage is transmitted to the on-time controller 19 through the feedback unit 18, and the on-time controller 19 is the feedback unit 18. The power controller 11 is controlled by the signal received from. In addition, the off-time control unit 16 detects the voltage transmitted through the transformer 13 during the power-off operation, recognizes the state of the load 15, and controls the power controller 11.

However, when the load 15 on the secondary side decreases and the load current becomes a minimum condition, the secondary voltage detection unit 17 can supply the load current only by the charge charged in the smoothing capacitor of the rectifying / smoothing unit 14. Since the incoming signal is hardly generated, the on-time delay time fed back from the feedback unit 18 is reduced. Therefore, since the on-time holding time of the on-time control unit 19 becomes smaller than the on-time holding limit of the power controller 11, the power controller 11 is prevented from on / off control and the on-time time is increased. Therefore, the secondary output voltage is increased to operate the overvoltage protection device, which is a protection circuit inside the power controller 11, to cut off the secondary power.

FIG. 2 is a detailed circuit diagram of a control block diagram of a conventional switching mode power supply. As shown in FIG. 2, when the voltage detected by the secondary voltage detector 17 is higher than the reference voltage, the second power supply VCC2 is connected through the resistor R2. A photodiode (PD) to be turned on by receiving the photodiode (PD), a phototransistor (PT) for receiving the light of the photodiode (PD) and receiving the first power supply (VCC1) through the resistor (R1), and conducting the same; A grounded capacitor (C) charged with a current of PT), a grounded resistor (R3) connected in parallel with the capacitor (C) to discharge charge charged in the capacitor (C), and the transistor (PT) And a power controller 11 connected between the capacitor and the capacitor C and operating in accordance with the voltage value of the resistor R3.

In the partial detailed circuit diagram of the switching mode power supply control block diagram configured as described above, when the voltage detected by the secondary voltage detector 17 is higher than the reference voltage, the second power supply VCC2 is applied through the resistor R2 to receive the photodiode ( PD) lights up. In response to the light of the photodiode PD, the phototransistor PT conducts the first power supply VCC1 through the resistor R1 to charge the capacitor C. The capacitor C discharges the charged charge through the resistor R3, and the power controller 11 cuts off the power supply to the secondary side by the voltage value of the resistor R3. Therefore, conventionally, the control circuit of the switching mode power supply is used to supply a stable power to the load.

However, in the prior art as described above, in order to recover the secondary power cut off due to the reduction of the load, the power supply voltage of the power controller must be discharged to a predetermined voltage or less after completely removing the power supply. There is a problem in that it takes time and manpower due to restart, causing inconvenience to the user.

Therefore, the present invention devised in view of the above problems, the control signal fed back when the secondary load current is reduced, the switching mode power supply can not control the switching mode power supply to prevent this The object of the present invention is to provide a power latch prevention circuit.

1 is a block diagram of a conventional switching mode power supply control.

2 is a partial detailed circuit diagram of a conventional switched mode power supply control block diagram.

3 is a block diagram of a power latch prevention circuit of the invention switching mode power supply.

Figure 4 is a power latch prevention circuit diagram of the switched mode power supply of the present invention.

***** Explanation of symbols for the main parts of the drawing *****

11,21: power controller 12,22: power transistor

13,23: transformer 14,24: rectifier / smooth

15,25: load 16,26: off-time controller

17, 27: secondary voltage detection unit 18, 28: feedback unit

19,29: On time control unit 30: On time detection unit

31: controller power control unit

The present invention for achieving the above object, the power controller for controlling the power of the load, the power transistor to operate on / off by receiving the output signal of the power controller, and receives the output signal of the power transistor A transformer for transforming a primary side AC voltage and transferring it to a secondary side, an off-time controller for controlling an off time of the power controller by sensing a voltage transmitted through the transformer when the power transistor is turned off, and an output alternating current in the transformer A rectification / smoothing unit configured to receive DC into a direct current, a secondary voltage detector comparing the DC voltage detected by the rectifier / smoothing unit with a reference voltage, and feeding back a difference between the detected voltage and the reference voltage by the secondary voltage detector. A feedback unit, an on-time controller for receiving an output signal of the feedback unit, and controlling an on-time time; An on-time detector for detecting an on-time holding time of the control unit smaller than an on-time holding limit of the power controller to increase the output voltage of the transformer and transmitting the detected signal to the on-time control unit; And a controller power controller configured to stabilize the power of the power controller by receiving the signal detected by the time detector.

Hereinafter, the operation and effect of the power latch prevention circuit of the switching mode power supply according to the present invention will be described with reference to FIGS. 3 and 4.

3 is a block diagram of a power latch prevention circuit of the switching mode power supply of the present invention. As shown therein, a power controller 21 for controlling the power of the load 25 and an output signal of the power controller 21 are shown. A power transistor 22 that operates on / off by receiving an input, a transformer 23 that receives an output signal of the power transistor 22, transforms a primary AC voltage, and transmits the secondary voltage to a secondary side; and the power transistor 22 ) Detects the voltage transmitted through the transformer 23 during the off operation, and controls the off time of the power controller 21, and receives an output alternating current from the transformer 23 to a direct current. The rectification / smoothing section 24, the secondary voltage detecting section 27 for comparing the DC voltage detected by the rectifying / smoothing section 24 and the reference voltage, and the detected voltage in the secondary voltage detecting section 27. Avoid feedbacking the difference in reference voltage The on-time controller 29 which controls the on-time time by receiving the output part of the back part 28, the feedback part 28, and the on-time holding time of the on-time controller 29 are the power controller 21. An on-time detection unit 30 which detects the output voltage of the transformer 23 when the output voltage of the transformer 23 is increased to be smaller than the on-time maintenance limit of the signal, and transmits the detected signal to the on-time control unit 29; The operation of the present invention constituted by the controller power control unit 31 for stabilizing the power of the power controller 21 by receiving the signal detected by the detection unit 30 will be described.

When the on signal output from the power controller 21 is applied to the power transistor 22, the primary side AC voltage becomes the secondary side AC voltage through the transformer 23 by the on operation of the power transistor 22, and rectified. DC is passed through the smoothing unit 24 and is transmitted to the secondary voltage detection unit 27 and the load 25. The voltage difference between the voltage detected by the secondary voltage detector 27 and the reference voltage is transmitted to the on-time controller 29 through the feedback unit 28, and the on-time controller 29 is the feedback unit 28. The power controller 21 is controlled by the signal received from. In addition, the off-time control unit 26 senses the voltage transmitted through the transformer 23 at power off, recognizes the state of the load 25 and controls the power controller 21.

When the load 25 on the secondary side decreases and the load current reaches a minimum condition, the load current can be supplied only by the electric charge charged in the smoothing capacitor of the rectifying / smoothing section 24, so that the load current enters the secondary voltage detector 27. Since the signal is hardly generated, the on-time delay time fed back from the feedback unit 28 is reduced. Therefore, the on-time holding time of the on-time control unit 29 is smaller than the on-time holding limit of the power controller 21, so that the power controller 21 is prevented from on / off control and the on-time time is increased so that the secondary side output The voltage increases.

The on-time detector 30 detects the increase of the secondary output voltage and transmits a detection signal to the controller power controller 31 and the on-time controller 29. The on-time controller 29 reduces the secondary output voltage by delaying the on-time time of the power controller 21, and when the secondary output voltage is smaller than the rated voltage of the load 25, the secondary voltage detector ( In step 27, the current fed back from the feedback unit 28 increases due to the difference between the reference voltage and the detected voltage, so that the on-time controller 29 changes the on-time and the power controller 21 performs stable operation.

In addition, the secondary output voltage is decreased by the delay of the on time time of the on-time controller 29, thereby reducing the voltage of the power controller 21 using the secondary output voltage as the voltage source. Accordingly, the controller power controller 31 supplies stable power to the power controller 21 by the signal output from the on time detector 30.

FIG. 4 is a detailed circuit diagram of the power latch prevention circuit of the switching mode power supply of the present invention. As shown in FIG. 4, when the voltage detected by the secondary voltage detection unit 27 is higher than the reference voltage, the second power supply is connected through the resistor R5. A photodiode (PCD) that is turned on by applying (VCC2), a phototransistor (PCT) that receives the light of the photodiode (PCD) and receives and conducts a first power supply (VCC1) through a resistor (R4); A grounded capacitor C1 charged with the current of the photo transistor PCT, a grounded resistor R6 connected in parallel with the capacitor C1 to discharge the charge charged in the capacitor C1, and the resistance; When the voltage applied to (R6) is applied to the predetermined voltage or more, the power controller 21 for increasing the off time and the first power supply (VCC1) is distributed to the resistor (R8) and resistor (R9) through the resistor (R8). The applied voltage as the reference voltage When a voltage is input and a comparator (CP) for outputting a predetermined signal; When the output voltage of the transformer 23 increases, a diode D for charging a grounded capacitor C2 by applying a voltage from the transformer 23 and applying a voltage to the comparator CP and the comparator CP A transistor Q1 for charging the capacitor C1 by conducting the first power source VCC1 applied through the resistor R7 according to a predetermined signal of the controller, and adjusting a voltage when power is supplied to the power controller 21. When the resistor R10 and the predetermined signal of the comparator CP are conducted, the resistor R10 is short-circuited and the transistor Q2 supplies the first power supply VCC1 to the power controller 21. The operation of the present invention configured as described above will be described.

When the voltage detected by the secondary voltage detector 27 is higher than the reference voltage, the second power source VCC2 is applied through the resistor R5 to turn on the photodiode PCD. In response to the light of the photodiode PCD, the phototransistor PCT conducts the first power supply VCC1 through the resistor R4 to charge the capacitor C1. The capacitor C1 discharges the charged charge through the resistor R6, and the power controller 21 cuts off the power supply to the secondary side when the voltage applied to the resistor R6 becomes higher than a predetermined voltage. However, when the load 25 on the secondary side decreases and the load current reaches a minimum condition, the secondary voltage detection unit 27 can supply the load current only by the electric charge charged in the smoothing capacitor of the rectifying / smoothing unit 24. Since the incoming signal is rarely generated, the on-time delay time fed back from the feedback unit 28 is reduced. Therefore, since the on-time holding time of the on-time control unit 29 becomes smaller than the on-time holding limit of the power controller 21, the power controller 21 is prevented from on / off control and the on-time time is increased so that the secondary side output Will increase the voltage.

The increased voltage at the secondary side charges the capacitor C2 through the diode D of the on-time detector 30 and is input to the comparator CP. The comparator CP receives the first power supply VCC1 through the resistor R8 and receives the voltage divided by the resistor R8 and the resistor R9 as a reference voltage to compare the voltage output from the diode D. do. When the comparator CP receives a voltage higher than the reference voltage, the comparator CP outputs a predetermined signal to conduct the transistor Q1 of the on-time controller 29 and the transistor Q2 of the controller power controller 31.

The transistor Q1 of the on-time controller 29 conducts the first power source VCC1 applied through the resistor R7 by a predetermined signal of the comparator CP to charge the capacitor C1. The capacitor C1 delays the on-time by applying a predetermined voltage to the power controller 21. When the on time is delayed, the secondary output voltage is decreased, so that the voltage of the power controller 21 using the secondary output voltage as the voltage source is decreased, thereby preventing normal operation. Accordingly, the transistor Q2 of the controller power control unit 31 receives the predetermined signal of the comparator CP to conduct the first power supply VCC1 so that the resistor R10 is short-circuited to stabilize the power controller 21. It will supply power.

As described in detail above, the present invention has a control signal fed back when the secondary load current decreases, so that the switching mode power supply cannot be controlled, thereby becoming a power latch mode. There is an effect that eliminates the inconvenience of the user to restart.

Claims (4)

A power controller for controlling the power of the load, a power transistor operating on / off by receiving the output signal of the power controller, and receiving the output signal of the power transistor to transform the primary AC voltage to the secondary A transformer, an off-time controller that senses a voltage transmitted through the transformer when the power transistor is turned off, and controls an off time of the power controller, a rectifying / smoothing unit receiving an output alternating current from the transformer and converting it into a direct current; A secondary voltage detector comparing the DC voltage detected by the rectifier / smoothing unit with a reference voltage, a feedback unit feeding back a difference between the detected voltage and the reference voltage from the secondary voltage detector, and an output signal of the feedback unit An on-time controller for controlling an on-time time, and an on-time holding time of the on-time controller is the power An on-time detector that detects the output voltage of the transformer when the output voltage of the transformer is increased by being smaller than the on-time maintenance limit of the controller, and transmits the detected signal to the on-time controller; and receives the signal detected by the on-time detector to receive the power. The power latch prevention circuit of the switching mode power supply characterized by comprising a controller power control unit for stabilizing the power supply of the controller. The display device of claim 1, wherein the on-time detector comprises: a diode receiving a predetermined current from a transformer; a capacitor connected between a cathode of the diode and a ground to charge a current received through the diode to form a predetermined voltage; A power latch preventing circuit of a switching mode power supply, characterized in that the power supply is divided into a resistor and applied as a reference voltage and a voltage higher than the reference voltage is inputted to output a predetermined signal. The electronic device of claim 1, wherein the on-time controller comprises: a grounded capacitor charged with current from the feedback unit; a transistor configured to charge the capacitor by conducting a first power source applied through a resistor by an output signal of the on-time detector; And a grounded resistor connected to the capacitor in parallel and configured to discharge a charge charged in the capacitor to apply a predetermined voltage to the power controller. The power supply controller of claim 1, wherein the controller power controller is configured to supply a first power supply to the power controller by shorting the resistance when the controller adjusts a voltage when power is supplied to the power controller and an output signal of the on-time detector is applied. The power latch prevention circuit of the switching mode power supply characterized by consisting of.