1. A ZVS approach for AC/DC converter with PFC
PowereLab HKU
A ZVS approach for AC/DC converter with PFC
The Power Electronics Lab., Hong Kong University
N. K. Poon C. P. Liu M. H. Pong
Speaker
Bryan M. H. Pong
Power eLab
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Prepared by Franki Poon

2. Some basic concepts Load
Input rectifiers and capacitor produce Pulsating input current
Harmonic currents are generated
Power eLab
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3. A conventional method A boost converter and a DC/DC converter Ipfc Idc
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4. A popular method among researchers
Ipfc
Idc
Single stage design which combines the boost and the DCDC converters
Power eLab
HKU
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5. Is single stage design always better?
Let us take a look
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6. Why two-stage design? Advantage Losses  Ipfc2 + Idc2
Fix DCDC input voltage
Controllable bulk voltage
Disadvantage
Need two controllers
One more MOSFET
Ipfc
Idc
Power eLab
HKU
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7. Why single-stage design?
Advantage
One controller
One MOSFET less
Disadvantage
Losses  (Ipfc + Idc)2
High Idc at low line
Higher Ipfc
High current stress
High voltage stress
Ipfc
Idc
Power eLab
HKU
Prepared by Franki Poon

8. Good reasons for two-stage
Advantages
Losses  Ipfc2 + Idc2
Fix DCDC input voltage
Controllable bulk voltage
Disadvantages
Need two controller
One more MOSFET
Single Stage
Advantages
One controller
One MOSFET less
Disadvantages
Losses  (Ipfc + Idc)2
High Idc at low line
Higher Ipfc
High current stress
High voltage stress
Power eLab
HKU
Prepared by Franki Poon

9. Our new idea Boost + Asymmetric half-bridge with soft switching
DMpfc > DM2 M1
Mpfc M2
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10. Zero voltage state - M2 M1 turn off then . . Power eLab HKU
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11. Zero voltage state - Mpfc
After M2 turn on
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12. Two separate converters
M2 turn on
Mpfc turn on
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13. Zero voltage state – M1 M2 turn off Mpfc turn on Power eLab HKU
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14. One cycle on asymmetric
M1 turn on
Mpfc turn on
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15. One cycle on PFC M1 turn on Mpfc turn off Power eLab HKU
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16. It’s great, but . . . No control for PFC !! If DMpfc < DM2
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17. After all – small Maux added
For all DMpfc and all DM2 M1
Maux
Mpfc M2
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18. Final timing arrangement
ZVS too M2
gate drive A M1
gate drive B
Maux
gate drive
Mpfc
gate drive
VA = VB
VMaux_ds = VA-VB =0
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19. guarantee a path for Laux current when M2 off at any time
Practical consideration M1
Maux
Mpfc
Doff M2
guarantee a path for Laux current when M2 off at any time
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20. Two diodes are used to clamp ringing
Practical circuit – O/P
250uH
IRF840A
Two diodes are used to clamp ringing
STD5NM50
12uH
8uH
STPS12NM50
STPS12NM50
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Active Diode
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21. Simplified timing circuit
M2 gate
O/P
Sync
M1 gate
Maux gate
Sync
L4981
Mpfc gate
O/P
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22. How does it look? A 120W, 12V10A AC adapter Width = 12.6cm
Depth = 6.3cm
Height = 1.9cm
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23. ZVS on M2
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24. ZVS on Mpfc Power eLab HKU
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25. ZVS on Mpfc & M2 Power eLab HKU
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26. Losses and Efficiency < 1W at no load 91% efficiency 12V@10A
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27. Finally . . .
Simple Boost + Asymmetric Half-bridge configuration – Good Combination.
All ZVS behaviors – Very little added cost.
Two separate converter – Easy to control
Active diode can be incorporated – <1W no load power
Simple PWM controller – simple ASIC
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