BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to power converters, and more particularly, relates to the soft switching power converters.
2. Description of the Related Art
Flyback power converters have been widely used to provide power supplies for electronic products, such as home appliances, computers, battery charger etc. For achieving higher efficiency and reducing power loss, the power converter can be designed to operate at the quasi-resonant (QR) switching when the power converter is operated at high input voltage and high switching frequency. The QR switching is preferred for reducing the switching losses and EMI. The present invention is an active-clamp circuit for the quasi-resonant (QR) flyback power converter. The objective of this invention is to improve the efficiency of the QR flyback power converter by recycling the stored energy of the leakage inductor of the power transformer of the QR flyback power converter and achieving the quasi-resonant soft-switching operation. Therefore, the QR flyback power converter can be operated at higher switching frequency for reducing the size of its power transformer. The related prior arts can be found in “Clamped Continuous Flyback Power Converter”, U.S. Pat. No. 5,570,278 and “Offset Resonance Zero Voltage Switching Flyback Converter” U.S. Pat. No. 6,069,803.
BRIEF SUMMARY OF THE INVENTION
It is an objective of the present invention to provide an active-clamp circuit for a quasi-resonant (QR) flyback power converter. It can recycle the stored energy of the leakage inductor of the power transformer of the QR flyback power converter and achieve the quasi-resonant soft-switching operation for improving the efficiency of the QR flyback power converter.
It is an objective of the present invention to provide an active-clamp circuit for a QR flyback power converter. It can make the QR flyback power converter being operated at higher switching frequency for reducing the size of its power transformer.
The active-clamp circuit for the QR flyback power converter according to the present invention comprises an active-clamper, a high-side transistor driver, a charge-pump circuit and a control circuit. The active-damper is connected to a primary winding of a power transformer of the QR flyback power converter in parallel. The high-side transistor driver is coupled to drive the active-damper. The charge-pump circuit is coupled to the high-side transistor driver to provide a power supply to the high-side transistor driver in accordance with a voltage source. The control circuit generates a control signal coupled to control the high-side transistor driver. The control signal is generated in response to a PWM signal and an input voltage of the QR flyback power converter.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention can be more fully understood by reading the subsequent detailed description and examples with references made to the accompanying drawings, wherein:
FIG. 1 shows a circuit diagram of a preferred embodiment of a QR flyback power converter according to the present invention.
FIG. 2A˜FIG. 2E show the circuit operations of the QR flyback power converter according to the present invention.
FIG. 3 shows the key waveforms of the QR flyback power converter including the PWM signal, the control signal and the high voltage signal according to the present invention.
FIG. 4 shows a circuit diagram of a preferred embodiment of the PWM controller according to the present invention.
FIG. 5 shows a circuit diagram of a preferred embodiment of the control circuit according to the present invention.
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a circuit diagram of a preferred embodiment of a QR flyback power converter according to the present invention. The QR flyback power converter includes a power transformer 10 having a primary winding NP in the primary side and a secondary winding NS in the secondary side. A first terminal of the primary winding NP is coupled to one terminal of an input capacitor CIN and receives an input voltage VIN. The other terminal of the input capacitor CIN is further coupled to a ground. A main-power transistor 20 is coupled to switch the primary winding NP of the power transformer 10 for regulating an output voltage VO at the output of the QR flyback power converter through a rectifier 40 and an output capacitor 45. A drain terminal of the main-power transistor 20 is coupled to a second terminal of the primary winding NP of the power transformer 10. A source terminal of the main-power transistor 20 is coupled to the ground. An anode of the rectifier 40 is coupled to one terminal of the secondary winding NS. The output capacitor 45 is coupled between a cathode of the rectifier 40 and the other terminal of the secondary winding NS. The output capacitor 45 is further coupled to the output of the QR flyback power converter in parallel.
A parasitic diode 25 is a body diode that is coupled to the main-power transistor 20 in parallel. A PWM controller 100 generates a PWM signal S1 coupled to a gate terminal of the main-power transistor 20 to drive the main-power transistor 20. That is, the PWM signal S1 is coupled to control the main-power transistor 20 of the QR flyback power converter for the regulation. The PWM signal S1 is generated in accordance with a feedback signal VFB. The feedback signal VFB is coupled to the output of the QR flyback power converter and correlated to the output voltage VO. The power transformer 10 further includes an auxiliary winding NA for generating a voltage source VCC via a rectifier 60 and a capacitor 65. An anode of the rectifier 60 is coupled to a first terminal of the auxiliary winding NA. A second terminal of the auxiliary winding NA is coupled to the ground. One terminal of the capacitor 65 is coupled to a cathode of the rectifier 60 and the PWM controller 100. The other terminal of the capacitor 65 is coupled to the ground. The voltage source VCC is further connected to supply the power to the PWM controller 100.
A resistor 80 is coupled from the first terminal of the auxiliary winding NA of the power transformer 10 to the PWM controller 100 for generating a sense signal VS at the PWM controller 100. An active clamp circuit comprises an active-clamper, a high-side transistor driver 50, a charge-pump circuit and a control circuit (LPC) 200 (shown in FIG. 4) of the PWM controller 100. A power transistor 30 is connected to a capacitor 15 in series to develop the active-clamper. The active-clamper is connected to the primary winding NP of the power transformer 10 in parallel. One terminal of the capacitor 15 is coupled to the first terminal of the primary winding NP, and the other terminal of the capacitor 15 is coupled to a drain terminal of the power transistor 30. A source terminal of the power transistor 30 is coupled to the second terminal of the primary winding NP and the drain terminal of the main-power transistor 20.
A parasitic diode 35 is a body diode that is coupled to the power transistor 30 in parallel. The high-side transistor driver 50 is coupled to a gate terminal of the power transistor 30 to drive the power transistor 30 of the active-clamper. Thus, the high-side transistor driver 50 is used to drive the active-damper. The charge-pump circuit is coupled to the high-side transistor driver 50 to provide a power supply to the high-side transistor driver 50 in accordance with the voltage source VCC. The charge-pump circuit is developed by a diode 70 coupled to the voltage source VCC and a charge-pump capacitor 75 coupled to the diode 70 in series. The charge-pump capacitor 75 is further coupled to the high-side transistor driver 50 in parallel. The PWM controller 100 generates a control signal S2 coupled to control the high-side transistor driver 50. The control signal S2 is generated in response to the PWM signal S1 and the sense signal VS. The control signal S2 can be turned on once the PWM signal S1 is turned off. The sense signal VS is correlated to the input voltage VIN of the power converter. The pulse width of the control signal S2 is generated in response the pulse width of the PWM signal S1 and the amplitude of the input voltage VIN.
From FIG. 2A to FIG. 2E shows the circuit operations of the QR flyback power converter according to the present invention. FIG. 2A shows that the main-power transistor 20 is turned on and the power transistor 30 is turned off, that is to say, the control signal S2 is off-state and the PWM signal S1 is on-state. When the main-power transistor 20 is turned on, the input voltage VIN will be added across the primary winding NP of the power transformer 10 and a switching current IP will flow through the main-power transistor 20. A voltage VNA is generated at the auxiliary winding NA of the power transformer 10, and the voltage VNA is coupled to the PWM controller 100 through the resistor 80 for generating the sense signal VS. The amplitude of the voltage VNA is correlated to the amplitude of the input voltage VIN and the turn ratio NA/NP of the power transformer 10. Furthermore, the charge-pump capacitor 75 is charged by the voltage source VCC through the diode 70.
FIG. 2B shows the main-power transistor 20 is turned off and the PWM signal S1 is off-state. When the main-power transistor 20 is turned off and the PWM signal S1 is off-state, the energy stored in the power transformer 10 will be transferred to the secondary winding NS of the power transformer 10 to generate the output voltage VO at the output of the QR flyback power converter, and it will be also transferred to the auxiliary winding NA to charge the capacitor 65 for the voltage source VCC via the rectifier 60. Meanwhile, the energy stored in the magnetized inductor and leakage inductor of the primary winding NP will be delivered to a parasitic capacitor CJ of the main-power transistor 20 and the capacitor 15 through the parasitic diode 35 of the power transistor 30. The parasitic capacitor CJ is coupled to the main-power transistor 20 in parallel.
FIG. 2C shows that once the parasitic diode 35 is forward-bias, the control signal S2 will be enabled to turn on the power transistor 30 through the high-side transistor driver 50. The energy stored in the capacitor 15 is thus able to deliver to the output voltage VO through the power transformer 10. FIG. 2D and FIG. 2E show that the power transistor 30 is turned off and the control signal S2 is off-state. FIG. 2D and FIG. 2E also show the quasi resonant operation. The energy stored in the parasitic capacitor CJ of the main-power transistor 20 will be charged to the magnetized inductor of the primary winding NP of the power transformer 10. After that, the energy stored in the magnetized inductor of the primary winding NP of the power transformer 10 will be delivered to discharge the parasitic capacitor CJ of the main-power transistor 20. Once the parasitic capacitor CJ of the main-power transistor 20 is discharged to a lower voltage, the PWM signal S1 is enabled to turn on the main-power transistor 20 for soft-switching operation. The detail description can be found in the prior art of “Power converter having phase lock circuit for quasi-resonant soft switching”, U.S. Pat. No. 7,466,569.
FIG. 3 shows the key waveforms of the QR flyback power converter including the PWM signal S1, the control signal S2 and a high voltage signal VP (shown in FIG. 2B) according to the present invention. The waveform of the sense signal VS is correlated to the waveform of the high voltage signal VP at the drain terminal of the main-power transistor 20. The PWM signal S1 is coupled to control the main-power transistor 20 (shown in FIG. 1) of the QR flyback power converter for the regulation. The main-power transistor 20 is coupled to switch the primary winding NP of the power transformer 10. The pulse width of the PWM signal S1 is an on-time TON. The control signal S2 is generated after a delay time TD when the PWM signal S1 is turned off. The pulse width of the control signal S2 is shorter than the demagnetization time TDS of the power transformer 10. Therefore, the control signal S2 is turned off before the power transformer 10 is fully demagnetized. The quasi-resonant time TQR shows the quasi-resonant period of the high voltage signal VP. The PWM signal S1 is turned on during a valley voltage of the high voltage signal VP for reducing the switching loss of the main-power transistor 20.
FIG. 4 is a circuit diagram of a preferred embodiment of the PWM controller 100 according to the present invention. The PWM controller 100 includes a PWM circuit (PWM) 150 and the control circuit (LPC) 200. The control circuit 200 is a linear-predict circuit that receives the PWM signal S1 and the sense signal VS and generates the control signal S2 in accordance with the pulse width of the PWM signal S1 and the amplitude of the sense signal VS. The control signal S2 is coupled to control the high-side transistor driver 50 for turning on/off the power transistor 30. The sense signal VS is correlated to the input voltage VIN of the power converter. The pulse width of the control signal S2 is proportional to the pulse width of the PWM signal S1 and the amplitude of the input voltage VIN. In other words, the pulse width of the control signal S2 is generated in response to the pulse width of the PWM signal S1 and the amplitude of the input voltage VIN. The PWM circuit 150 receives the feedback signal VFB and the sense signal VS and generates the PWM signal S1 in response to the feedback signal VFB and the sense signal VS. The description of the PWM circuit 150 can be found in the prior-art of “Switching control circuit for primary-side controlled power converters”, U.S. Pat. No. 7,362,592, so here is no detailed description about it.
FIG. 5 is a circuit diagram of a preferred embodiment of the control circuit 200 according to the present invention. The control circuit 200 includes an input voltage-detection circuit (VIN—DET) 210 coupled to receive the sense signal VS for generating a voltage signal VA. The description and the detail operation of the input voltage-detection circuit 210 can be found in the prior art of “Detection circuit for sensing the input voltage of transformer”, U.S. Pat. No. 7,671,578. A voltage-to-current converter (V/A) 215 receives the voltage signal VA to generate a charge current IC. The charge current IC is utilized to charge a capacitor 250 via a switch 230 for generating a charge signal VC when the PWM signal S1 is on-state. The switch 230 is coupled between the voltage-to-current converter 215 and the capacitor 250. The capacitor 250 is further coupled to the ground.
A discharge current ID is coupled to discharge the capacitor 250 via a switch 235 when the PWM signal S1 is off-state. The switch 235 is coupled between the discharge current ID and the capacitor 250. The discharge current ID is further coupled to the ground. The PWM signal S1 is coupled to control the on/off status of the switch 230, and the PWM signal S1 is coupled to control the on/off status of the switch 235 through an inverter 225. Through the inverter 225 and a time-delay circuit (DLY) 270, the PWM signal S1 is coupled to a clock input CK of a flip-flop 290. Therefore, the flip-flop 290 will generate the control signal S2 at an output Q of the flip-flop 290 after the delay time TD (shown in FIG. 3) when the PWM signal S1 is turned off. An output of the inverter 225 is coupled to the time-delay circuit 270. The time-delay circuit 270 is coupled to the clock input CK of the flip-flop 290. An input D of the flip-flop 290 is supplied with the voltage source VCC.
A threshold voltage VT is supplied with a positive input of a comparator 260. A negative input of the comparator 260 is coupled to the switches 230, 235 and the capacitor 250 for receiving the charge signal VC at the capacitor 250 to compare with the threshold voltage VT. A first input of an NAND gate 265 is coupled to an output of the comparator 260. A second input of the NAND gate 265 is coupled to the time-delay circuit 270 and the output of the inverter 225. An output of the NAND gate 265 is connected to a reset input R of the flip-flop 290 to reset the flip-flop 290 for switching off the control signal S2 when the charge signal VC is lower than the threshold voltage VT. It is to say, the control signal S2 is switched off before the power transformer 10 (shown in FIG. 1) is full demagnetized.
It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the present invention without departing from the scope or spirit of the invention. In view of the foregoing, it is intended that the present invention cover modifications and variations of this invention provided they fall within the scope of the following claims and their equivalents.