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Transcript
Chapter 2
Power Electronic
Devices
Bi-polar Transistor (BJT)
(C)
(C)
(C)
IC
Collector
Base
(B)
VCB
N
IB
(B)
P
N
VCE
(B)
VBE
Emitter
IE
(E)
(E)
IC   I B
I E  I B  IC
(E)
VCE  VCB  VBE
(C)
Characteristics of Bi-polar
Transistor
IC
VCB
IB
VCE
(B)
VBE
IE
IB
Saturation Region
IC
(E)
IB1
IB2< IB1
Linear Region
IB= 0
V
0.6
BE
Base Characteristics
Cut Off Region
VCE
Collector Characteristics
IC
IB max
IC
RL
VCC
RL
IB
(1)
V CE
V CC
(2)
IB = 0
VCC  VCE  RL IC
At point (1)
VCE is very small
VCC
IC 
RL
Closed
switch
Open
switch
VCC
At point (2)
IC is very small
VCE  VCC
VCE
Main Features of BJT
• Current controlled device
– Base current must be present during the
closing period
– High base losses
• Low current gain in the saturation
region
• Can operate at high frequencies
Field Effect Transistor (FET)
ID
(D)
V GS1
ID
VGS2 < V GS1
(G)
VDS
VGS3 < V GS2
VGS
0 < VGS4 < V GS3
(S)
VDS
Main Features of FET
• Voltage controlled device
• Low gate losses
Thyristors (Four Layer Diode)
Anode (A)
Anode (A)
IA
Anode (A)
IA
IA
P
N
P
N
P
N
P
VRB
Q1
Q2
N
PIh
N
Ic2
Q1
Ic1
Q2
VBO
IA
Cathode (K)
Cathode (K)
Cathode (K)
VAK
Thyristors [Silicon Controlled Rectifier
(SCR)]
Anode (A)
I
A
Ig = max
Ig > 0
Gate (G)
VRB
Ig = 0
Ih
V
AK
Cathode (K)
V
TO
VBO
Closing Conditions of SCR
1. Positive anode to
cathode voltage
(VAK)
2. Maximum
triggering pulse is
applied (Ig)
Anode (A)
Gate (G)
Cathode (K)
Closing angle is a
Opening Conditions of SCR
1. Anode current is
below the holding
value (Ih)
VRB
I
A
Ig = 0
Ih
V
AK
Opening angle is 
Ratings of Power Electronic Devices
• Steady State Circuit ratings:
• The current and voltage of the circuit
should always be less than the
device ratings.
Ratings of Power Electronic Devices
• Junction temperature: Losses inside
solid-state devices are due to
impurities of their material as well as
the operating conditions of their
circuits.
Ratings of Power Electronic Devices
• During the conduction period, the voltage drop across
the solid-state device is about one volt. This voltage
drop multiplied by the current inside the device
produces losses.
• When the device is in the blocking mode (open), a
small amount of leakage current flows inside the
device which also produces losses.
• The gate circuits of the SCRs and FETs, and the
base circuits of the transistors, produce losses due to
their triggering signals.
• Every time the solid state device is turned on or off,
switching losses are produced. These losses are
usually higher for faster devices, and for devices
operating in high frequency modes.
Ratings of Power Electronic Devices
• Surge current: It is the absolute
maximum of the non-repetitive impulse
current
Ratings of Power Electronic Devices
• Switching time:
• Turn-on time is the interval between applying
the triggering signal and the turn-on of the
device.
• The turn-off time is the interval from the onstate to the off-state.
• The larger the switching time the smaller is the
operating frequency of the circuit.
Ratings of Power Electronic Devices
• Critical rate of rise of current (or
maximum di/dt): A solid-state device
can be damaged if the di/dt of the circuit
exceeds the maximum allowable value
of the device. di/dt damage can occur
even if the current is below the surge
limit of the device. To protect the device
from this damage, a snubbing circuit for
di/dt must be used.
Ratings of Power Electronic Devices
• Critical rate of rise of voltage (or
maximum dv/dt): When dv/dt across a
device exceeds its allowable limit, the
device is forced to close. This is a form
of false triggering. It may lead to
excessive current or excessive di/dt. To
protect the device against excessive
dv/dt, a snubbing circuit for dv/dt must
be used.
di/dt and dv/dt Protection
R
s
Cs
+ -
Ls
Load
V
© M. A. El-Sharkawi, University of
Washington
32
Closing Switch
Cs
+ -
Rs
I2
Ls
V
Load impedance
I
Load
1
Z L  R  j L 
1
j C
© M. A. El-Sharkawi, University of
Washington
33
Closing Switch: Analysis of I1
Ls
V
I1 ( S ) 
I
Load
1
LL, RL, CL
V (S )
1 

 R  SL 

CS 

© M. A. El-Sharkawi, University of
Washington
L  Ls  LL
34
Closing Switch: Analysis of I1
Ls
V
i1 (t ) 
I
C V n
(1   )
2
Load
1

e  n t sin n (1   2 ) t

1
R C
n 
; 
LC
2 L
© M. A. El-Sharkawi, University of
Washington
35
Snubbing Circuit: Ls
di1  CV n2  n t

e
sin [n (1   2 ) t ]CV n2 e  n t cos[n (1   2 ) t ]
dt
(1   2 )
Worst Scenario for Maximum di/dt: When the load capacitor is not charged at t=0
di1
dt
max
 CV 
2
n
V
 di1 

 dt 
  max L
1
n 
LC
V
Ls 
 LL
 di1 
 
 dt  max
VBO
Ls 
 LL
 di 
0.1  
 dt  rating
© M. A. El-Sharkawi, University of
Washington
36
Closing Switch: Analysis of I2
The fully charged cap discharges after the switch is closed
Ls
V
Vo
i2 
e
Rs
Cs
+ -
Rs
I2
t

Rs C s
Load
 Vo
di2

e
2
dt Rs C s
© M. A. El-Sharkawi, University of
Washington

t
Rs C s
37
Closing Switch: Analysis of I2
Cs
+ -
Rs
Ls
V
 Vo
di2

e
dt Rs2 C s
t

Rs C s
At t = 0
I2
Load
 Vo
 di2 
 dt   R 2 C
max
s
s
 di2 
 di 
Let    0.1 
 dt  max
 dt  rating
© M. A. El-Sharkawi, University of
Washington
38
Opened Switch
Rs
Cs
+ -
Ls
V
I
Load
3
Load impedance
1
Z L RL  j LL 
j C L
© M. A. El-Sharkawi, University of
Washington
39
Opened Switch
Cs
+ -
Rs
Ls
R  Rs  RL
V
I
I3 (S ) 
3
V (S )
Load
L  Ls  LL
Cs C L
C
Cs  C L
1 

 R  SL 

CS 

© M. A. El-Sharkawi, University of
Washington
40
Opened Switch
Assume the caps are initially discharged
Cs
+ -
Rs
Vsw  Rs i3
Ls
dVsw
di3
 Rs
dt
dt
V
I
3
Load
dVsw
V
 Rs
dt
L
© M. A. El-Sharkawi, University of
Washington
41
Selection of the Snubbing Circuit Parameters
Step 1: Compute snubbing inductance
VBO
Ls 
 LL
di
 
0.1 
 dt  rating
Step 2: Compute snubbing Resistance
dVsw
V
 Rs
dt
L
Step 3: Compute snubbing Capacitance
 Vo
 di 
0.1 
 2
 dt  rating Rs Cs
© M. A. El-Sharkawi, University of
Washington
42