L6 semiconductor-power-switching-devices-3-130912210901-phpapp01

Semiconductor Power Switching Devices-3
(Lecture-6)
R S Ananda Murthy
Associate Professor and Head
Department of Electrical & Electronics Engineering,
Sri Jayachamarajendra College of Engineering,
Mysore 570 006
R S Ananda Murthy Semiconductor Power Switching Devices-3

TRIAC
MT2
MT1
G
Circuit Symbol
of TRIAC
J1
J2
J3
Structure of TRIAC
+ indicates heavily doped region
- indicates lightly doped region
MT1
MT2
G
J4
ON
OFF
ON
OFF
MT2 positive
w.r.t. MT1 and
G positive w.r.t. MT1
Pulse triggered
MT2 negative
w.r.t. MT1 and
G negative w.r.t. MT1
Pulse triggered
MT1 MT2
G
TRIAC is equivalent to
two SCRs in anti-parallel
Shorting of p1 region to n3 region due to MT2 metal contact,
and the p2 region to the n2 region due to MT1 metal contact
results in two anti-parallel SCR structures: p1n1p2n2 and
p2n1p1n3.

TRIAC used in ACVC
VRMS
Constant
f
AC
ACVCV,
AC
Variable
same as inputf
(a)
vi vo
(b)
Triac+
−
R
+
−
vi
vo
tω
tω
(c)
0
Trigger
0
Trigger Trigger
π 2π
π 2π

Limitations of TRIAC as Compared to SCRs
Has lower dv/dt rating.
Requires well designed R-C snubber connected across it
to limit dv/dt.
Has longer turn-off time.
Has lower power handling capability.
Typically used in small motor speed regulators,
temperature control, illumination control, liquid level
control, phase control circuits, power switches.
Cannot be used in A.C. systems of frequency more than
400 Hz.

Speciﬁcations of TRIAC BT139

Diac
MT1
MT2
P
N
P
J1
J2
MT1
MT2
MT1
MT2
Structure and symbols of diac
Diacs are typically used to trigger TRIACS in ceiling fan
regulators and light dimming circuits.

Typical Diac Speciﬁcations

Simple Fan Regulator Circuit using TRIAC
Diac DB2 is used to trigger TRIAC BT136.

Some High Power TRIACS
(Source: www.china-rectifier.com)

Ratings of Some High Power TRIACS

Gate Turn Off Thyristor (GTO)
A
K
G
J1
J2
J3
Buffer layer
A
K
G
Anode contact
Buffer layer structure Anode shorted structure
Anode short
A A
K K
GG
Circuit symbols of GTO
Increases reverse voltage
blocking capability
Decreases reverse voltage
blocking capability
A
K
G
Inter digitized gate-cathode structure increases di/dt rating of
the device and also improves turn-off performace of the device.

Static Characteristic of GTO
A
K
G
Circuit Symbol
of GTO
ON
OFF
= Latching Current
= Holding Current
Forward
Leakage
Current
Symmetrical
GTO
Asymmetrical
GTO

Control Characteristics of GTO
vo
iG
vo
+
−
iG
t
V
t
+
−
GTO
RV
GTO can be turned on by applying a positive gate current
pulse and turned off by applying a negative gate current
pulse.
To prevent unwanted turn-off during transients, it is
recommended to apply a low value of continuous positive
gate current as long as GTO has to be kept on.

GTO Compared with SCR
GTO SCR
Fully-controlled Semi-controlled
VON = 3-4 V VON =1.5-2 V
Higher IL and IH IL and IH very low compared to GTO
Assymetric GTO has very low VBR Has VBR ≈ VBO
Typically dv/dt = 1000 V/µs Typically dv/dt =200-500 V/µs
Turn-off Current Gain: 6-15 Not applicable
Max. operating frequency: 1-4 kHz Typcally operated at 50 or 60 Hz

Photographs of GTOs
Asymmetric Type Reverse Blocking Type

Stud Type GTO

Speciﬁcations of Asymmetric GTOs

Speciﬁcations of Symmetric GTOs

Next Lecture...
In the next lecture we will discuss some more power
semiconductor switching devices used in power electronics.
Thank You.

L6 semiconductor-power-switching-devices-3-130912210901-phpapp01

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