COMCHIP P6KE10C-G

600W Transient Voltage Suppressor
SMD Diodes Specialist
P6KE-G Series
Stand-off Voltage: 6.8 ~ 400V
Power Dissipation: 600 Watts
RoHS Device
Features
DO-15
-Plastic package has underwriters laboratory
flammability classification 94V-0
-600W, surge capability at 1mS.
-Excellent clamping capability.
-Low Zener impedance.
-Fast response time: typically less than 1.0pS from
0 volt to BV min.
-Typical I R less than 1μA above 10V.
0.034(0.9)
0.028(0.7)
1.0(25.4)
MIN.
0.300(7.6)
0.230(5.8)
0.140(3.6)
0.104(2.6)
Mechanical Data
-Case: Molded plastic DO-15
-Terminals: Axial leads solderable per MIL-STD202, Method 208
-Polarity: Color band denotes positive end
(cathode)
-Weight: 0.4 gram (0.014oz.)
1.0(25.4)
MIN.
Dimensions in inches and (millimeter)
Maximum Ratings and Electrical Characteristics
Symbol
Value
Unit
Peak power dissipation at T A =25 OC
T P =1mS
(Note 1)
P PK
600
W
Steady state power dissipation at T L =75 OC
Lead length 0.375" (9.5mm) (Note 2)
PD
5.0
W
Peak forward surge current, 8.3mS single
half sine-wave superimposed on rated load
(JEDEC method) (Note 3)
I FSM
100
A
Operating junction and storage temperature
range
T J , T STG
-55 to +175
Parameter
O
C
NTOES:
(1) Non-repetitive current pulse, per fig.3 and derated above T A =25 OC per fig. 2.
(2) Mounted on copper land area of 1.57in 2(40mm 2).
(3) 8.3mS single half-sine wave, duty cycle=4 pulses per minute maximum.
(4) For bidirectional use C suffix for 10% tolerance, CA suffix for 5% tolerance.
REV:A
QW-BTV06
Page 1
600W Transient Voltage Suppressor
SMD Diodes Specialist
RATING AND CHARACTERISTIC (P6KE-G Series)
Breakdown Voltage
Part No.
B BR (V)
@IT(mA)
Working Maximum Maximum Maximum Maximum
Peak
Reverse Reverse Clamping Temperature
Reverse Leakage Current
Voltage Coefficient of
Voltage
at V RW M
IRSM
V RW M
V RR
V RW M (V)
IR(μA)
(A)
(V)
(%C)
MIN.
MAX.
P6KE6.8(C)-G
6.12
7.48
10
5.50
1000
56.0
10.8
0.057
P6KE6.8(C)A-G
6.45
7.14
10
5.80
1000
57.0
10.5
0.057
P6KE7.5(C)-G
6.75
8.25
10
6.05
500
51.0
11.7
0.061
P6KE7.5(C)A-G
7.13
7.88
10
6.40
500
53.0
11.7
0.061
P6KE8.2(C)-G
7.38
9.02
10
6.63
200
48.0
12.5
0.065
P6KE8.2(C)A-G
7.79
8.61
10
7.02
200
50.0
12.1
0.065
P6KE9.1(C)-G
8.19
10.0
1.0
7.37
50
44.0
13.8
0.068
P6KE9.1(C)A-G
8.65
8.55
1.0
7.78
50
45.0
13.4
0.068
P6KE10(C)-G
9.00
11.0
1.0
8.10
10
40.0
15.0
0.073
P6KE10(C)A-G
9.50
10.5
1.0
8.55
10
41.0
14.5
0.073
P6KE11(C)-G
9.90
12.1
1.0
8.92
5.0
37.0
16.2
0.075
P6KE11(C)A-G
10.5
11.6
1.0
9.40
5.0
38.0
15.6
0.075
P6KE12(C)-G
10.8
13.2
1.0
9.72
5.0
35.0
17.3
0.078
P6KE12(C)A-G
11.4
12.6
1.0
10.2
5.0
36.0
16.7
0.078
P6KE13(C)-G
11.7
14.3
1.0
10.5
5.0
32.0
19.0
0.081
P6KE13(C)A-G
12.4
13.7
1.0
11.1
5.0
33.0
18.2
0.081
P6KE15(C)-G
13.5
16.5
1.0
12.1
5.0
27.0
22.0
0.084
P6KE15(C)A-G
14.3
15.8
1.0
12.8
5.0
28.0
21.2
0.084
P6KE16(C)-G
14.4
17.6
1.0
12.9
5.0
26.0
23.5
0.086
P6KE16(C)A-G
15.2
16.8
1.0
13.6
5.0
27.0
22.5
0.086
P6KE18(C)-G
16.2
19.8
1.0
14.5
5.0
23.0
26.5
0.088
P6KE18(C)A-G
17.1
18.9
1.0
15.3
5.0
24.0
25.2
0.088
P6KE20(C)-G
18.0
22.0
1.0
16.2
5.0
21.0
29.1
0.090
P6KE20(C)A-G
19.0
21.0
1.0
17.1
5.0
22.0
27.7
0.090
P6KE22(C)-G
19.8
24.2
1.0
17.8
5.0
19.0
31.9
0.092
P6KE22(C)A-G
20.9
23.1
1.0
18.8
5.0
20.0
30.6
0.092
P6KE24(C)-G
21.6
26.4
1.0
19.4
5.0
17.0
34.7
0.094
P6KE24(C)A-G
22.8
25.2
1.0
20.5
5.0
18.0
33.2
0.094
P6KE27(C)-G
24.3
29.7
1.0
21.8
5.0
15.0
39.1
0.096
P6KE27(C)A-G
25.7
28.4
1.0
23.1
5.0
16.0
37.5
0.096
P6KE30(C)-G
27.0
33.0
1.0
24.3
5.0
14.0
43.5
0.097
P6KE30(C)A-G
28.5
31.5
1.0
25.6
5.0
14.4
41.4
0.097
P6KE33(C)-G
29.7
36.3
1.0
26.8
5.0
12.6
47.7
0.098
P6KE33(C)A-G
31.4
34.7
1.0
28.2
5.0
13.2
45.7
0.098
P6KE36(C)-G
32.4
39.6
1.0
29.1
5.0
13.2
45.7
0.099
P6KE36(C)A-G
34.2
37.8
1.0
30.8
5.0
12.0
49.9
0.099
P6KE39(C)-G
35.1
42.9
1.0
31.6
5.0
10.6
56.4
0.100
P6KE39(C)A-G
37.1
41.0
1.0
33.3
5.0
11.2
53.9
0.100
P6KE43(C)-G
38.7
47.3
1.0
34.8
5.0
9.6
61.9
0.101
P6KE43(C)A-G
40.9
45.2
1.0
36.8
5.0
10.1
59.3
0.101
REV:A
QW-BTV06
Page 2
600W Transient Voltage Suppressor
SMD Diodes Specialist
RATING AND CHARACTERISTIC (P6KE-G Series)
B re a k d o w n V o lta g e
P a rt N o .
B B R (V )
@ I T (m A )
W o rk in g
Peak
R e v e rs e
V o lta g e
V R W M (V )
M a x im u m
R e v e rs e
Leakage
at V RW M
I R (μ A )
M a x im u m M a x im u m
M a x im u m
R e v e rs e C la m p in g T e m p e ra tu re
C u rre n t
V o lta g e C o e ffic ie n t o f
IR S M
V RW M
V RR
(A )
(V )
(% C )
M IN .
M AX.
P 6 K E 4 7 (C )-G
4 2 .3
5 1 .7
1 .0
3 8 .1
5 .0
8 .9
6 7 .8
0 .1 0 1
P 6 K E 4 7 (C )A -G
4 4 .7
4 9 .4
1 .0
4 0 .2
5 .0
9 .3
6 4 .8
0 .1 0 1
P 6 K E 5 1 (C )-G
4 5 .9
5 6 .1
1 .0
4 1 .3
5 .0
8 .2
7 3 .5
0 .1 0 2
P 6 K E 5 1 (C )A -G
4 8 .5
5 3 .6
1 .0
4 3 .6
5 .0
8 .6
7 0 .1
0 .1 0 2
P 6 K E 5 6 (C )-G
5 0 .4
6 1 .6
1 .0
4 5 .4
5 .0
7 .4
8 0 .5
0 .1 0 3
P 6 K E 5 6 (C )A -G
5 3 .2
5 8 .8
1 .0
4 7 .8
5 .0
7 .8
7 7 .0
0 .1 0 3
P 6 K E 6 2 (C )-G
5 5 .8
6 8 .2
1 .0
5 0 .2
5 .0
6 .8
8 9 .0
0 .1 0 4
P 6 K E 6 2 (C )A -G
5 8 .9
6 5 .1
1 .0
5 3 .0
5 .0
7 .1
8 5 .0
0 .1 0 4
P 6 K E 6 8 (C )-G
6 1 .2
7 4 .8
1 .0
5 5 .1
5 .0
6 .1
9 8 .0
0 .1 0 4
P 6 K E 6 8 (C )A -G
6 4 .6
7 1 .4
1 .0
5 8 .1
5 .0
6 .5
9 2 .0
0 .1 0 4
P 6 K E 7 5 (C )-G
6 7 .5
8 2 .5
1 .0
6 0 .7
5 .0
5 .5
1 0 8 .0
0 .1 0 5
P 6 K E 7 5 (C )A -G
7 1 .3
7 8 .5
1 .0
6 4 .1
5 .0
5 .8
1 0 3 .0
0 .1 0 5
P 6 K E 8 2 (C )-G
7 3 .8
9 0 .2
1 .0
6 6 .4
5 .0
5 .1
1 1 8 .0
0 .1 0 5
P 6 K E 8 2 (C )A -G
7 7 .9
8 6 .1
1 .0
7 0 .1
5 .0
5 .3
1 1 3 .0
0 .1 0 5
P 6 K E 9 1 (C )-G
8 1 .9
1 0 0 .0
1 .0
7 3 .7
5 .0
4 .5
1 3 1 .0
0 .1 0 6
P 6 K E 9 1 (C )A -G
8 6 .5
9 5 .5
1 .0
7 7 .8
5 .0
4 .8
1 2 5 .0
0 .1 0 6
P 6 K E 1 0 0 (C )-G
9 0 .0
1 1 0 .0
1 .0
8 1 .0
5 .0
4 .2
1 4 4 .0
0 .1 0 6
P 6 K E 1 0 0 (C )A -G
9 5 .0
1 0 5 .0
1 .0
8 5 .5
5 .0
4 .4
1 3 7 .0
0 .1 0 6
P 6 K E 1 1 0 (C )-G
9 9 .0
1 2 1 .0
1 .0
8 9 .2
5 .0
3 .8
1 5 8 .0
0 .1 0 7
P 6 K E 1 1 0 (C )A -G
1 0 5 .0
1 1 6 .0
1 .0
9 6 .0
5 .0
4 .0
1 5 2 .0
0 .1 0 7
P 6 K E 1 2 0 (C )-G
1 0 8 .0
1 3 2 .0
1 .0
9 7 .2
5 .0
3 .5
1 7 3 .0
0 .1 0 7
P 6 K E 1 2 0 (C )A -G
1 1 4 .0
1 2 6 .0
1 .0
1 0 2 .0
5 .0
3 .6
1 6 5 .0
0 .1 0 7
P 6 K E 1 3 0 (C )-G
1 1 7 .0
1 4 3 .0
1 .0
1 0 5 .0
5 .0
3 .2
1 8 7 .0
0 .1 0 7
P 6 K E 1 3 0 (C )A -G
1 2 4 .0
1 3 7 .0
1 .0
1 1 1 .0
5 .0
3 .3
1 7 9 .0
0 .1 0 7
P 6 K E 1 5 0 (C )-G
1 3 5 .0
1 6 5 .0
1 .0
1 2 1 .0
5 .0
2 .8
2 1 5 .0
0 .1 0 8
P 6 K E 1 5 0 (C )A -G
1 4 3 .0
1 5 8 .0
1 .0
1 2 8 .0
5 .0
2 .9
2 0 7 .0
0 .1 0 8
P 6 K E 1 6 0 (C )-G
1 4 4 .0
1 7 6 .0
1 .0
1 3 0 .0
5 .0
2 .6
2 3 0 .0
0 .1 0 8
P 6 K E 1 6 0 (C )A -G
1 5 2 .0
1 6 8 .0
1 .0
1 3 6 .0
5 .0
2 .7
2 1 9 .0
0 .1 0 8
P 6 K E 1 7 0 (C )-G
1 5 3 .0
1 8 7 .0
1 .0
1 3 8 .0
5 .0
2 .5
2 4 4 .0
0 .1 0 8
P 6 K E 1 7 0 (C )A -G
1 6 2 .0
1 7 9 .0
1 .0
1 4 5 .0
5 .0
2 .6
2 3 4 .0
0 .1 0 8
P 6 K E 1 8 0 (C )-G
1 6 2 .0
1 9 8 .0
1 .0
1 4 6 .0
5 .0
2 .3
2 5 8 .0
0 .1 0 8
P 6 K E 1 8 0 (C )A -G
1 7 1 .0
1 8 9 .0
1 .0
1 5 4 .0
5 .0
2 .4
2 4 6 .0
0 .1 0 8
P 6 K E 2 0 0 (C )-G
1 8 0 .0
2 2 0 .0
1 .0
1 6 2 .0
5 .0
2 .1
2 8 7 .0
0 .1 0 8
P 6 K E 2 0 0 (C )A -G
1 9 0 .0
2 1 0 .0
1 .0
1 7 1 .0
5 .0
2 .2
2 7 4 .0
0 .1 0 8
P 6 K E 2 2 0 (C )-G
1 9 8 .0
2 4 2 .0
1 .0
1 7 5 .0
5 .0
1 .7 5
3 4 4 .0
0 .1 0 8
P 6 K E 2 2 0 (C )A -G
2 0 9 .0
2 3 1 .0
1 .0
1 8 5 .0
5 .0
1 .8 3
3 2 8 .0
0 .1 0 8
P 6 K E 2 5 0 (C )-G
2 2 5 .0
2 7 5 .0
1 .0
2 0 2 .0
5 .0
1 .6 7
3 6 0 .0
0 .1 1 0
P 6 K E 2 5 0 (C )A -G
2 3 7 .0
2 6 3 .0
1 .0
2 1 4 .0
5 .0
1 .7 5
3 4 4 .0
0 .1 1 0
P 6 K E 3 0 0 (C )-G
2 7 0 .0
3 3 0 .0
1 .0
2 4 3 .0
5 .0
1 .4 0
4 3 0 .0
0 .1 1 0
P 6 K E 3 0 0 (C )A -G
2 8 5 .0
3 1 5 .0
1 .0
2 5 6 .0
5 .0
1 .4 5
4 1 4 .0
0 .1 1 0
P 6 K E 3 5 0 (C )-G
3 1 5 .0
3 8 5 .0
1 .0
2 8 4 .0
5 .0
1 .2 0
5 0 4 .0
0 .1 1 0
P 6 K E 3 5 0 (C )A -G
3 3 2 .0
3 6 8 .0
1 .0
3 0 0 .0
5 .0
1 .2 5
4 8 2 .0
0 .1 1 0
P 6 K E 4 0 0 (C )-G
3 8 0 .0
4 2 0 .0
1 .0
3 4 2 .0
5 .0
1 .1 0
5 4 8 .0
0 .1 1 0
P 6 K E 4 0 0 (C )A -G
3 9 6 .0
4 8 4 .0
1 .0
3 5 6 .0
5 .0
0 .9 5
6 3 0 .0
0 .1 1 3
NOTES:
1. V BR measured after I T applied for 300μS, I T =square wave pulse or equivalent.
2. Surge current wave form per fig.3 and derated per fig.2.
3. V F =3.5V at I F =50A (P6KE6.8-G thru P6KE91A-G
V F =5.0V at I F =50A (p6KE100-G thru P6KE400A-G on ½ square or equivalent sine wave.
P W =8.3mS, duty cycle=4 pulses per minute max..
4. For bipolar types having V RWM of 10 Volts and under, the I R limit is doubled.
REV:A
QW-BTV06
Page 3
600W Transient Voltage Suppressor
SMD Diodes Specialist
RATING AND CHARACTERISTIC CURVES (P6KE-G Series)
Fig.1 Peak Pulse Power Rating Curve
Fig.2 Pulse Derating Curve
100
P PPM ,Peak Pulse Power (kW)
10
1.0
0.1
0.1 μS
1.0 μS
10μS
100μS
1.0mS
10mS
Peak Pulse Power (P PP ) or
Current(I PP ) Derating in Percentge (%)
100
Non-repetitive
pulse waveform
shown in fig.3
T A =25 OC
75
50
25
10
0
Fig.3 Pulse Wave Form
150
200
6000
C J , Junction Capacitance (pF)
Pulse width (td) is
defined as the point
where the peak current
decays to 50% of I PP
tr=10μS
I PPK , Peak Pulse Current (%)
100
Fig.4 Typical Junction Capacitance
Unidirectional
150
Peak value,
I PPM
100
Half value,
I PP /2
10/1000μS
waveform as
deined by R.E.A
50
T J =25OC
f=1MHz
Vsig=50mV PP
Measured at
zero bias
1000
Measured at
stand off
voltage, V WM
100
td
0
10
0
2
1
3
1
4
t, Time (mS)
I FSM , Peak Forward Surge Current (A)
60Hz
Resistive or
inductive load
L=0.375"(9.5mm)
Lead lengths
2.50
1.6" 1.6" 0.040"
(40" 40" 1mm)
Copper heat sinks
1.25
0
0
25
50
75
100
125
100
200
Fig.6 Maximum Non-repetitive
Forward Surge Current Unidirectional
5.00
3.75
10
V BR , Breakdown Voltage (V)
Fig.5 Steady State Power
Derating Curve
PM (AV) , Steady State Power
Dissipation (W)
50
TA, Ambient Temperature ( OC)
td, Pulse Width (sec)
150
175
T L , Lead Temperature ( OC)
200
200
8.3mS single half
sine-wave
(JEDEC method)
100
10
1
10
100
Number of Cycles at 60Hz
REV:A
QW-BTV06
Page 4
600W Transient Voltage Suppressor
SMD Diodes Specialist
RATING AND CHARACTERISTIC CURVES (P6KE-G Series)
Fig.7 Typical Reverse Leakage
Characteristics
I O, Instantaneous Reverse
Leakage Current (μA)
1000
100
Measured at
devices stand-off
Voltage, V WM
10
1
0.1
O
T A =25 C
0.01
0.001
0
100
200
300
400
500
V R , Breakdown Voltage (V)
REV:A
QW-BTV06
Page 5