1. EET426 Power Electronics II
Isolated Forward Converter
Prepared by : Mohd Azrik Roslan
EET 426 – Power Electronis II

2. What you should know after this lecture
DC Transformer concept
Isolated buck converter circuit
Isolated converter advantages and disadvantages
Ideal and real transformer review
Leakage inductance
Overlap loss
EET 426 – Power Electronis II

3. DC Transformer Concept
EET 426 – Power Electronis II

4. EET 426 – Power Electronis II
Buck Converter
Ei n
Vout C R L
Limitation of basic converter
Single input  Single output
No isolation  Can cause prob during fault
Output voltage relative to the input (based on duty cycle only)
Basic converter have several limitations:
Single input  Single output
No isolation  Can cause prob during fault
Output voltage relative to the input (based on duty cycle only)
EET 426 – Power Electronis II

5. ISOLATED BUCK CONVERTER
TRANSFORMER
INSERTION
POINT
Ei n
Vout C R L
EET 426 – Power Electronis II

6. ISOLATED BUCK CONVERTER
Vout R C
Ei n
no need for 2 primary side switches in series
DC TRANSFORMER CONCEPT
NOT REQUIRED:
EET 426 – Power Electronis II

7. ISOLATED BUCK CONVERTER
Vout R C
Ei n
Dfwd
winding polarity (dot notation) ensures
D1 forward biased when mosfet is on
Dfwd reverse biased when mosfet is on
resulting in forward transfer of energy
EET 426 – Power Electronis II

8. ISOLATED BUCK CONVERTER
Vout R C
Ei n
Dfwd
Usually for N-Channel Mosfet, low side switching has easier drive requirement
LOW-SIDE mosfet: easier drive requirements
EET 426 – Power Electronis II

9. ISOLATED BUCK CONVERTER
Vout R C
Ei n
Dfwd
NO CORE DEMAGNETISATION PATHWAY
EET 426 – Power Electronis II

10. EET 426 – Power Electronis II
Problem
When the transistor switch is off the transformer core must be fully reset by the end of the switching cycle.
This is to avoid core saturation and the resulting increase in switch current the next time it turns on.
The time available for reset reduces as the switch duty cycle increases hence reset must be possible during the minimum switch off -time.
EET 426 – Power Electronis II

11. ISOLATED BUCK CONVERTER
Vout C
Ei n
Dfwd
Dreset
DEMAGNETISATION PATHWAY
EET 426 – Power Electronis II

12. ISOLATED BUCK CONVERTER+ + D1
Vout
OFF R C
Ei n + ON
Dfwd
OFF
Dreset
MOSFET is ON
EET 426 – Power Electronis II

13. ISOLATED BUCK CONVERTER
MOSFET is ON
EET 426 – Power Electronis II

14. ISOLATED BUCK CONVERTER
Vout C
Ei n
Dfwd
Dreset ON
OFF
winding polarity (dot notation) ensures
Dreset forward biased when mosfet is off
D1 reverse biased when mosfet is off
EET 426 – Power Electronis II

15. ISOLATED BUCK CONVERTER
OFF L + D1
Vout ON R + C
Ei n
Dfwd + ON
OFF
Dreset
MOSFET is OFF
EET 426 – Power Electronis II

16. ISOLATED BUCK CONVERTER
MOSFET is OFF
EET 426 – Power Electronis II

17. EET 426 – Power Electronis II

18. Isolated converter advantages
Possible to have multiple outputs
No common input-output connection (increase safety)  Indirect converter
Output voltage polarity choice
Depending upon winding polarity
Output voltage can be varied dependent upon
Turns ratio
Duty cycle
EET 426 – Power Electronis II

19. Isolated converter disadvantages
Extra
Cost
Size
Weight
Increase losses
Winding resistance
Core loss
Leakage inductance overlap
Reduce output voltage
Produce transient voltages
Possible to have core saturation
Need core reset
EET 426 – Power Electronis II

20. Leakage Inductance Overlap
EET 426 – Power Electronis II

21. EET 426 – Power Electronis II
Ideal Transformer
VPRIM
VSEC
IPRIM
ISEC NP NS
POWER BALANCE
 =100%
EET 426 – Power Electronis II

22. EET 426 – Power Electronis II
Ideal Transformer
Function
Transfer energy
Scale current and voltage
Magnetic device
Provide electrical isolation
No energy storage
EET 426 – Power Electronis II

23. EET 426 – Power Electronis II
REAL TRANSFORMER
Have some energy storage
Magnetizing inductance (within core)
Can be minimized by using
gapless core
High permeability core
Leakage inductance (external to core)
Low frequency  core saturation
SMPS frequency  core loss
Low frequency can cause core saturation
SMPS frequency can cause core loss
EET 426 – Power Electronis II

24. REAL TRANSFORMER NP NS RC LM IMAG
practical magnetic cores have finite permeability
magnetising current IMAG required to establish core flux
effect represented by magnetising inductance LM
Practical transformer have
Finite magnetization current
Finite energy associated with this magnetization current
Leakage inductance in the winding
CORE LOSS represented by RC
EET 426 – Power Electronis II

25. represented by PRIMARY & SECONDARY winding resistance
REAL TRANSFORMER RP RS NP NS RC LM
Rp = Resistance of primary winding
Rs = Resistance of secondary winding
winding copper loss
represented by PRIMARY & SECONDARY winding resistance
EET 426 – Power Electronis II

26. Leakage Inductance Parasitic Element
EET 426 – Power Electronis II

27. TRANSFORMER LEAKAGE INDUCTANCE RP
LLP
LLS RS NP NS RC LM
TRANSFORMER LEAKAGE INDUCTANCE
inductive parameter of transformers (& inductors )
due to imperfect magnetic linking between windings
magnetic flux that does not link primary-secondary windings
represented as primary & secondary series inductive impedances
EET 426 – Power Electronis II

28. Leakage Inductance Effects
NEED to know VALUE
ISOLATED FORWARD CONVERTER
REDUCES OUTPUT VOLTAGE
NEGATIVE EFFECT
Vout
Ei n C R L
SCH1
SCH2
VS,2 VS VP
LL.P
LL.s
NP: NS
NORMALLY STEP DOWN
EET 426 – Power Electronis II

29. LEAKAGE INDUCTANCE MEASUREMENT
LL,P NP NS
LCR
meter
OPEN
CIRCUIT
LPRIM
LCR meter primary : LL,P +LPRIM
LEAKAGE INDUCTANCE
is an INTEGRAL PROPERTY of the TRANSFORMER
IMPOSSIBLE to measure DIRECTLY
EET 426 – Power Electronis II

30. LEAKAGE INDUCTANCE MEASUREMENT
LL,P NP NS
LCR
meter
PERFECT
SHORT
CIRCUIT
LPRIM
LCR meter primary : LL,P
EET 426 – Power Electronis II

31. EET 426 – Power Electronis II
ISOLATED FORWARD CONVERTER
Vout
Ei n C R L
SCH1
SCH2
VS,2 VS VP
LL.P
LL.s
NP: NS
NORMALLY STEP DOWN
VS < VP
IS > IP
EET 426 – Power Electronis II

32. IMPEDANCE TRANSFORMATIONNP NS
VSEC
VPRIM
ISEC
IPRIM
ZSEC
ZPRIM
STEP DOWN CONVERTERS
EET 426 – Power Electronis II

33. IMPEDANCE TRANSFORMATION
LL,P
VSEC
VPRIM NS NP
VSEC
VPRIM
LL(reflected)
STEP DOWN CONVERTERS
LL(reflected)< LL,P
EET 426 – Power Electronis II

34. EET 426 – Power Electronis II
ISOLATED FORWARD CONVERTER
Vout
Ei n C R L
SCH1
SCH2
VS,2 VS VP
NP: NS
NORMALLY STEP DOWN
LL.P
LL.r
VS < VP
IS > IP
EET 426 – Power Electronis II

35. ISOLATED FORWARD CONVERTER: OVERLAP
Vout
Ei n C R L
SCH1
SCH2
VS,2 VS VP
LL,r NP NS
Vgs
Ids
ISCH1
ISCH2
Leakage inductance prevents instantaneous commutation between the output rectifiers D1 and D2 resulting in two overlap intervals during which both devices are conducting, as shown in Fig E2-3 .The overlap interval tov1 results in an effective reduction of duty cycle at Vfilter which in turn creates a reduction in output voltage. The output voltage being zero during tov2 is therefore not affected by the second overlap interval.
LEAKAGE INDUCTANCE prevents
instantaneous commutation
between SCH1 SCH2
2 overlap intervals
SCH1 & SCH2 ON
SCH2 ON
VS,2 = 0
EET 426 – Power Electronis II

36. ISOLATED FORWARD CONVERTER: OVERLAP
Ei n C R L
SCH1
SCH2
VS,2 VS VP
LL,r NP NS
Vgs
Ids
ISCH1
Vout
ISCH2
VSEC
OVERLAP INTERVAL 2
NO EFFECT on Vout
The overlap interval tov1 results in an effective reduction of duty cycle at Vfilter which in turn creates a reduction in output voltage. The output voltage being zero during tov2 is therefore not affected by the second overlap interval.
OVERLAP INTERVAL 1
Vs,2
 DUTY CYCLE REDUCTION
VL,r
OUTPUT VOLTAGE LOSS
DUE to OVERLAP
Tsw
tovlap
DswTsw
EET 426 – Power Electronis II

37. ISOLATED FORWARD CONVERTER: OVERLAP
Ei n C R L
SCH1
SCH2
VS,2 VS VP
LL,r NP NS
Vgs
VSEC
Vs,2
Vout
VL,r
Tsw
tovlap
DswTsw
during overlap
Effective Duty Cycle LOSS
EET 426 – Power Electronis II

38. ISOLATED FORWARD CONVERTER: OVERLAP
Ei n C R L
SCH1
SCH2
VS,2 VS VP
LL,r NP NS
Vgs
VSEC
Vs,2
Vout
VL,r
Tsw
tovlap
DswTsw
during overlap
Vout LOSS
NON EFFICIENCY RELATED Vout LOSS
EET 426 – Power Electronis II

39. Isolated Forward Converter Analysis
EET 426 – Power Electronis II

40. inductor ‘rind’ power loss
input voltage
Ein
transformer primary turns np
transformer secondary turns ns
secondary current maximum
Is(max)
primary current max
Ip(max)
transistor switch duty cycle
Dsw
transistor on-state resistance
rdson
transistor power loss
Pmosfet
output current
Iout
inductor ‘resistance’
rind
inductor ‘rind’ power loss
Pr,ind
rectifier D1 and D2 voltage drops VF
DATA SHEET
rectifier D1 and D2 current max
Iak,max
combined D1 and D2 duty cycle
Drects 1
combined D1 and D2 loss
Prects
transformer primary loss
Pprim
transformer secondary loss
Psec
EET 426 – Power Electronis II

41. ‘ideal’ output voltage
total power loss
Ploss,total
input power
Pin
output power
Pout
efficiency 
‘ideal’ output voltage
Vout(ideal)
‘real’ output voltage
Vout real
EFFICIENCY RELATED VOUT LOSS
EET 426 – Power Electronis II

42. NON-EFFICIENCY RELATED VOUT LOSS
txer leakage inductance
(ref prim)
Lleak(prim)
(ref sec)
Lleak(sec)
average output voltage
‘overlap’ loss
output voltage
Vout
NON-EFFICIENCY RELATED VOUT LOSS
LEAKAGE INDUCTANCE RELATED VOUT LOSS
EET 426 – Power Electronis II

43. NON-EFFICIENCY RELATED VOUT LOSS
‘effective’
duty cycle loss
output voltage
Vout
NON-EFFICIENCY RELATED VOUT LOSS
LEAKAGE INDUCTANCE RELATED VOUT LOSS
EET 426 – Power Electronis II

44. EET 426 – Power Electronis II
Example 1
200 V
Dsw = 0.3
Table shows component parameter and operational information for the isolated forward converter shown in the figure. Determine
the isolated forward converter output voltage
the isolated forward converter efficiency
the mosfet voltage requirement
EET 426 – Power Electronis II

45. EET 426 – Power Electronis II
Example 2
200 V
Dsw = 0.4
Table shows component parameter and operational information for the isolated forward converter shown in the figure. Determine
the isolated forward converter output voltage
the isolated forward converter efficiency
EET 426 – Power Electronis II