Working Peak Reverse Voltage: 5.0 - 170 Volts
Power Dissipation: 3000 Watts
TV30C5V0 Thru TV30C171
Features
Ideal for surface mount applications
Easy pick and place
Plastic package has Underwriters Lab.
flammability classification 94V-0
Typical IR less than 1uA above 10V
Fast reponse time: typically less 1nS for
uni-direction, less than 5nS for bi-
directiona, from 0 V to BV min.
Mechanical data
Case: JEDEC DO-214AB molded plastic
Terminals: solderable per MIL-STD-750,
method 2026
Polarity: Cathode band denoted
Mounting position: Any
Approx. Weight:0.21 gram
SMD Transient Voltage Suppressor
SMD Transient Voltage Suppressor
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COMCHIP
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Maximum Ratings and Electrical Characterics
Rating at 25 C ambient temperature unless otherwise specified.
Single phase, half wave, 60Hz, resistive or inductive load.
For capacitive load, derate current by 20%
MDS0211017A
Page 1
Characteristics
Peak Power Dissipation on 10/1000uS
Waveform (Note 1, Fig. 1)
Peak Pulse Current of on 10/1000uS
Waveform (Note 1, Fig. 3)
Steady State Power Dissipation at
T
L
=75 C (Note 2)
Peak Forfard Surge Current, 8.3mS Single
Half Sine-Wave Superimposed on Rated
Load, Uni-Directional Only (Note 3)
Maxinum Instantaneous Forward Voltage
at 100A for Uni-Directional only
(Note 3 & 4)
Operation Junction Temperature Range
Storage Temperature Range
Symbol
P
PPM
I
PPM
P
M(AV)
I
FSM
VF
Tj
T
STG
Note: 1. Non-Repetitive Current Pulse, per Fig. 3 and Derated above TA=25 C, per Fig. 2.
2. Mounted on 8.0x8.0 mm . Copper Pads to Each Terminal.
3. Measured on 8.3 mS Single Half Sine-Wave or Equivalent Square Wave, Duty Cycle=4 Pulse per Minute Maximum.
4. VF=3.5V on TV30C5V0 thru TV30C900 Devices and VF=5.0V on TV30C101 thru TV30C171.
Value
3000
See Table 1
5.0
250
3.5/5.0
-55 to +150
-55 to +150
Units
Watts
A
Watts
A
Volts
C
C
SMC/DO-214AB
Dimensions in inches and (millimeter)
0.008(0.20)
0.0203(0.10)
0.124(3.15)
0.108(2.75)
0.103(2.62)
0.079(2.00)
0.050(1.27)
0.030(0.76)
0.245(6.22)
0.220(5.59)
0.280(7.11)
0.260(6.60)
0.012(0.31)
0.006(0.15)
0.320(8.13)
0.305(7.75)
Rating and Characteristic Curves (TV30C5V0 Thru TV30C171)
Fig. 1 - Reverse Characteristics
Fig. 2 - Pulse Derating Curve
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COMCHIP
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0.1 1.0 10 100 1000 10000
MDS0211017A
Page 2
SMD Transient Voltage Suppressor
SMD Transient Voltage Suppressor
100
10
1.0
0.1
Non-Repetitive
Pulse Waveform
Shown in Fig. 3
T
A
=25 C
Mounted on 8mmx8mm
Copper Pads
Pulse Width, t
d
(uS)
P
e
a
k
P
u
l
s
e
P
o
w
e
r
,
P
P
P
M
(
K
W
)
0 25 50 75 100 125 150 175
Ambient Temperature,T
A
( C)
Ambient Temperature,T
A
( C)
P
e
a
k
p
u
l
s
e
P
o
w
e
r
(
P
p
p
)
o
r
C
u
r
r
e
n
t
(
I
p
p
)
D
e
r
a
t
i
n
g
i
n
P
e
r
c
e
n
t
(
%
)
140
120
100
80
60
40
20
0
Fig. 4 - Typical Junction Capacitance
J
u
n
c
t
i
o
n
C
a
p
a
c
i
t
a
n
c
e
,
C
j
(
p
F
)
Breakdown Voltage,V
BR
(Volts)
100,000
10,000
1000
100
5.0 10 100 500
Tj=25 C
f=1.0MHz
Vsig=50mVp-p
Fig. 6 - Maxinum Non-Repetitive Peak
Forward Surge Current (Uni-
Directional Only)
P
e
a
k
F
o
r
w
a
r
d
S
u
r
g
e
C
u
r
r
e
n
t
,
I
F
S
M
(
A
)
350
300
250
200
150
100
50
0
1 10 100
Number of Cycle at 60Hz
Mounted on
5mmx5mm
Copper pads
Fig. 3 - Pulse Waveform
Time, t (mS)
0 1.0 2.0 3.0 4.0
125
100
75
50
25
0
Pulse Width (td) is Defined
as the Point Where the peak
Current Decay to 50% of Ipp
Peak Value I
PPM
Half Value Ipp/2
10/1000 uS Waveform
as Defined by R.E.A.
P
e
a
k
P
u
l
s
e
C
u
r
r
e
n
t
,
I
P
P
M
(
%
)
tr =10uS
Fig. 5 - Steady State Power Derating Curve
Leadt Temperature,T
L
( C)
S
t
e
a
d
y
S
t
a
t
e
P
o
w
e
r
D
i
s
s
i
p
a
t
i
o
n
,
P
M
(
A
V
)
,
W
a
t
t
s
60Hz
Resistive or
Inductive
Load
Mounted on
8mmx8mm
Copper pads
7.0
6.0
5.0
4.0
3.0
2.0
1.0
0
0 25 50 75 100 125 150 175
Uni-Directional
Bi-Directional
Measure at
Zero Bias
Measure at
Standard-off
Voltage, Vwm
8.3mS Single Half Sine-Wave
(JEDEC Method) Tj=Tjmax
SMD Transient Voltage Suppressor
SMD Transient Voltage Suppressor
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COMCHIP
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MDS0211017A
Page 4
Note:
1) Suffix K denotes 10% tolerance devices, suffix J denotes 5% tolerance devices.
2) Suffix B after part number to specify bi-directional devices.
3) For bi-directional devices having VR of 10 volts and under, the IR limit is double.
P a r t N o .
V
R W M
V
B R M i n
V
B R M a x
I
T
I
F S M
I
R @
V
R W M
( V )
( V )
( V )
( mA )
(A) @8 .3mS
( V )
I p p ( A)
( uA )
U N I
B I
T V 3 0 C 4 8 0 K ( B )
4 8 . 0 0
5 3 . 3 0
6 7 . 5
1
2 5 0
8 5 . 5
3 5 . 0
5
H F W
IFW
T V 3 0 C 4 8 0 J ( B )
4 8 . 0 0
5 3 . 3 0
6 1 . 3
1
2 5 0
7 7 . 4
3 8 . 8
5
H F X
IFX
T V 3 0 C 5 1 0 K ( B )
5 1 . 0 0
5 6 . 7 0
7 1 . 8
1
2 5 0
9 1 . 1
3 7 . 0
5
H F Y
IFY
T V 3 0 C 5 1 0 J ( B )
5 1 . 0 0
5 6 . 7 0
6 5 . 2
1
2 5 0
8 2 . 4
3 6 . 4
5
H F Z
IFZ
T V 3 0 C 5 4 0 K ( B )
5 4 . 0 0
6 0 . 0 0
7 6 . 0
1
2 5 0
9 6 . 3
3 1 . 2
5
H G D
IGD
T V 3 0 C 5 4 0 J ( B )
5 4 . 0 0
6 0 . 0 0
6 9 . 0
1
2 5 0
8 7 . 1
3 4 . 4
5
H G E
IGE
T V 3 0 C 5 8 0 K ( B )
5 8 . 0 0
6 4 . 4 0
8 1 . 6
1
2 5 0
1 0 3 . 0
3 9 . 2
5
H G F
IGF
T V 3 0 C 5 8 0 J ( B )
5 8 . 0 0
6 4 . 4 0
7 4 . 1
1
2 5 0
9 3 . 6
3 2 . 0
5
H G G
IGG
T V 3 0 C 6 0 0 K ( B )
6 0 . 0 0
6 6 . 7 0
8 4 . 5
1
2 5 0
1 0 7 . 0
2 8 . 0
5
H G H
IGH
T V 3 0 C 6 0 0 J ( B )
6 0 . 0 0
6 6 . 7 0
7 6 . 7
1
2 5 0
9 6 . 8
3 1 . 0
5
H G K
IGK
T V 3 0 C 6 4 0 K ( B )
6 4 . 0 0
7 1 . 1 0
9 0 . 1
1
2 5 0
1 1 4 . 0
2 6 . 4
5
H G L
IGL
T V 3 0 C 6 4 0 J ( B )
6 4 . 0 0
7 1 . 1 0
8 1 . 8
1
2 5 0
1 0 3 . 0
2 9 . 2
5
H G M
IGM
T V 3 0 C 7 0 0 K ( B )
7 0 . 0 0
7 7 . 8 0
9 8 . 6
1
2 5 0
1 2 5 . 0
2 4 . 0
5
H G N
IGN
T V 3 0 C 7 0 0 J ( B )
7 0 . 0 0
7 7 . 8 0
8 9 . 5
1
2 5 0
1 1 3 . 0
2 6 . 6
5
H G P
IGP
T V 3 0 C 7 5 0 K ( B )
7 5 . 0 0
8 3 . 3 0
1 0 5 . 7
1
2 5 0
1 3 4 . 0
2 2 . 4
5
H G Q
IGQ
T V 3 0 C 7 5 0 J ( B )
7 5 . 0 0
8 3 . 3 0
9 5 . 8
1
2 5 0
1 2 1 . 0
2 4 . 8
5
H G R
IGR
T V 3 0 C 7 8 0 K ( B )
7 8 . 0 0
8 6 . 7 0
1 0 9 . 8
1
2 5 0
1 3 9 . 0
2 1 . 6
5
H G S
IGS
T V 3 0 C 7 8 0 J ( B )
7 8 . 0 0
8 6 . 7 0
9 9 . 7
1
2 5 0
1 2 6 . 0
2 2 . 8
5
H G T
IGT
T V 3 0 C 8 5 0 K ( B )
8 5 . 0 0
9 4 . 4 0
1 1 9 . 2
1
2 5 0
1 5 1 . 0
1 9 . 8
5
H G U
IGU
T V 3 0 C 8 5 0 J ( B )
8 5 . 0 0
9 4 . 4 0
1 0 8 . 2
1
2 5 0
1 3 7 . 0
2 0 . 8
5
H G V
IGV
T V 3 0 C 9 0 0 K ( B )
9 0 . 0 0
1 0 0 . 0 0
1 2 6 . 5
1
2 5 0
1 6 0 . 0
1 8 . 8
5
H G W
IGW
T V 3 0 C 9 0 0 J ( B )
9 0 . 0 0
1 0 0 . 0 0
1 1 5 . 5
1
2 5 0
1 4 6 . 0
2 0 . 6
5
H G X
IGX
T V 3 0 C 1 0 1 K ( B )
1 0 0 . 0 0
1 1 1 . 0 0
1 4 1 . 0
1
2 5 0
1 7 9 . 0
1 6 . 6
5
H G Y
IGY
T V 3 0 C 1 0 1 J ( B )
1 0 0 . 0 0
1 1 1 . 0 0
1 2 8 . 0
1
2 5 0
1 6 2 . 0
1 8 . 6
5
H G Z
IGZ
T V 3 0 C 1 1 1 K ( B )
1 1 0 . 0 0
1 2 2 . 0 0
1 5 4 . 5
1
2 5 0
1 9 6 . 0
1 5 . 4
5
H H D
IHD
T V 3 0 C 1 1 1 J ( B )
1 1 0 . 0 0
1 2 2 . 0 0
1 4 0 . 5
1
2 5 0
1 7 7 . 0
1 6 . 8
5
H H E
IHE
T V 3 0 C 1 2 1 K ( B )
1 2 0 . 0 0
1 3 3 . 0 0
1 6 9 . 0
1
2 5 0
2 1 4 . 0
1 4 . 0
5
H H F
IHF
T V 3 0 C 1 2 1 J ( B )
1 2 0 . 0 0
1 3 3 . 0 0
1 5 3 . 0
1
2 5 0
1 9 3 . 0
1 5 . 6
5
H H G
IHG
T V 3 0 C 1 3 1 K ( B )
1 3 0 . 0 0
1 4 4 . 0 0
1 8 2 . 5
1
2 5 0
2 3 1 . 0
1 3 . 0
5
H H H
IHH
T V 3 0 C 1 3 1 J ( B )
1 3 0 . 0 0
1 4 4 . 0 0
1 6 5 . 5
1
2 5 0
2 0 9 . 0
1 4 . 4
5
H H K
IHK
T V 3 0 C 1 5 1 K ( B )
1 5 0 . 0 0
1 6 7 . 0 0
2 1 1 . 5
1
2 5 0
2 6 8 . 0
1 1 . 2
5
H H L
IHL
T V 3 0 C 1 5 1 J ( B )
1 5 0 . 0 0
1 6 7 . 0 0
1 9 2 . 5
1
2 5 0
2 4 3 . 0
1 2 . 4
5
H H M
IHM
T V 3 0 C 1 6 1 K ( B )
1 6 0 . 0 0
1 7 8 . 0 0
2 2 6 . 0
1
2 5 0
2 8 7 . 0
1 0 . 4
5
H H N
IHN
T V 3 0 C 1 6 1 J ( B )
1 6 0 . 0 0
1 7 8 . 0 0
2 0 5 . 0
1
2 5 0
2 5 9 . 0
1 1 . 6
5
H H P
IHP
T V 3 0 C 1 7 1 K ( B )
1 7 0 . 0 0
1 8 9 . 0 0
2 3 9 . 5
1
2 5 0
3 0 4 . 0
9 . 8
5
H H Q
IHQ
T V 3 0 C 1 7 1 J ( B )
1 7 0 . 0 0
1 8 9 . 0 0
2 1 7 . 5
1
2 5 0
2 7 5 . 0
1 1 . 0
5
H H R
IHR
M a x V c
M a r k i n g C o d e
A b s o l u t e M a x i m u m R a t i n g ( T a = 2 5 C )
E l e c t r ic a l C h a r a c t e r is t i c s ( T a = 2 5 C )
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