PANJIT GLZJ18

DATA SHEET
GLZJ2.0~GLZJ56
SURFACE MOUNT ZENER DIODES
VOLTAGE
2.0 to 56 Volts
MINI-MELF/LL-34
500 mWatts
POWER
Unit : inch (mm)
FEATURES
• Planar Die construction
• 500mW Power Dissipation
• Ideally Suited for Automated Assembly Processes
.063(1.6)
.055(1.4)DIA.
• Both normal and Pb free product are available :
Normal : 80~95% Sn, 5~20% Pb
Pb free: 98.5% Sn above
MECHANICAL DATA
.020(0.5)
.012(0.3)
.020(0.5)
.012(0.3)
• Case: Molded Glass MINI-MELF
.146(3.7)
.130(3.3)
• Terminals: Solderable per MIL-STD-202E, Method 208
• Polarity: See Diagram Below
• Approx. Weight: 0.03 grams
• Mounting Position: Any
• Packing information
T/R - 2.5K per 7" plastic Reel
T/R - 10K per 13" plastic Reel
MAXIMUM RATINGS AND ELECTRICAL CHARACTERISTICS
P aram eter
S ym bol
Value
U nits
P TO T
500
mW
Junction Tem perature
TJ
175
O
C
S torage Tem perature R ange
TS
-65 to +175
O
C
P ow erD issipation atTam b = 25
O
C
Valid provided thatleads ata distance of10m m from case are keptatam bienttem perature.
P aram eter
Therm alR esistance Junction to A m bientA ir
Forw ard Voltage atIF = 100m A
S ym bol
M in.
Typ.
M ax.
U nits
R thA
--
--
0.3
K /m W
VF
--
--
1
V
Valid provided thatleads ata distance of10m m from case are keptatam bienttem perature.
STAD-SEP.14.2004
PAGE . 1
PART NUMBER
C LA S S
GLZJ 2.0
GLZJ 2.2
GLZJ 2.4
GLZJ 2.7
GLZJ 3.0
GLZJ 3.3
GLZJ 3.6
GLZJ 3.9
GLZJ 4.3
GLZJ 4.7
GLZJ 5.1
GLZJ 5.6
GLZJ 6.2
GLZJ 6.8
GLZJ 7.5
GLZJ 8.2
GLZJ 9.1
GZLJ 10
GLZJ 11
STAD-SEP.14.2004
V Z @ IZT
M IN . V
MAX. V
IZ
(m A )
VR
(V )
IR ( U A )
MA X
IZT
(m A )
Z ZT (Ω)
MA X
IZK
(m A)
Z ZK (Ω)
MA X
5
0.5
120
5
100
0.5
1000
5
0.7
100
5
100
0.5
1000
5
1.0
120
5
100
0.5
1000
M a r k i ng
Code
A
1.88
2.10
B
2.02
2.20
A
2.12
2.30
B
2.22
2.41
A
2.33
2.52
B
2.43
2.63
A
2.54
2.75
B
2.69
2.91
A
2.85
3.07
B
3.01
3.22
A
3.16
3.38
B
3.32
3.53
A
3.46
3.69
B
3.60
3.84
A
3.74
4.01
B
3.89
4.16
A
4.04
4.29
B
4.17
4.43
C
4.30
4.57
A
4.44
4.68
B
4.55
4.80
C
4.68
4.93
A
4.81
5.07
B
4.94
5.20
C
5.09
5.37
A
5.28
5.55
B
5.45
5.73
C
5.61
5.91
A
5.78
6.09
B
5.96
6.27
C
6.12
6.44
A
6.29
6.63
B
6.49
6.83
C
6.66
7.01
A
6.85
7.22
B
7.07
7.45
C
7.29
7.67
A
7.53
7.92
B
7.78
8.19
C
8.03
8.45
A
8.29
8.73
B
8.57
9.01
C
8.83
9.30
Z9C1
A
9.12
9.59
Z10A
B
9.41
9.90
C
9.70
10.20
D
9.94
10.44
A
10.18
10.71
B
10.50
11.05
C
10.82
11.38
5
1.0
100
5
110
0.5
1000
5
1.0
50
5
120
0.5
1000
5
1.0
20
5
120
0.5
1000
5
1.0
10
5
100
1
1000
5
1.0
5
5
100
1
1000
5
1.0
5
5
100
1
1000
Z2A0
Z2B0
Z2A2
Z2B2
Z2A4
Z2B4
Z2A7
Z2B7
Z3A0
Z3B0
Z3A3
Z3B3
Z3A6
Z3B6
Z3A9
Z3B9
Z4A3
Z4B3
Z4C3
Z4A7
5
1.0
5
5
90
1
900
Z4B7
Z4C7
Z5A1
5
1.5
5
5
80
1
800
Z5B1
Z5C1
Z5A6
5
2.5
5
5
60
1
500
Z5B6
Z5C6
Z6A2
5
3.0
5
5
60
1
300
Z6B2
Z6C2
Z6A8
5
3.5
2
5
20
0.5
150
Z6B8
Z6C8
Z7A5
5
4.0
0.5
5
20
0.5
120
Z7B5
Z7C5
Z8A2
5
5.0
0.5
5
20
0.5
120
Z8B2
Z8C2
Z9A1
5
5
6.0
7.0
0.5
0.2
5
5
25
30
0.5
0.5
120
120
Z9B1
Z10B
Z10C
Z10D
Z11A
5
8.0
0.2
5
30
0.5
120
Z11B
Z11C
PAGE . 2
Part Number
C LA S S
GLZJ 12
GLZJ 13
GLZJ 15
GLZJ 16
GLZJ 18
GLZJ 20
GLZJ 22
GLZJ 24
GLZJ 27
GLZJ 30
GLZJ 33
GLZJ 36
GLZJ 39
V Z @ IZT
M i n. V
M a x. V
A
11.13
11.71
B
11.44
12.03
C
11.74
12.35
A
12.11
12.75
B
12.55
13.21
C
12.99
13.66
IZ
(m A )
VR
(V )
IR ( u A )
MA X
Iz t
(mA )
Z ZT (Ω)
MA X
IZK
(m A)
Z ZK (Ω)
MA X
5
9.0
0.2
5
30
0.5
110
M a r k i ng
code
Z12A
Z12B
Z12C
Z13A
5
10
0.2
5
35
0.5
110
Z13B
Z13C
A
13.44
14.13
B
13.89
14.62
C
14.35
15.09
A
14.80
15.57
B
15.25
16.04
C
15.69
16.51
A
16.22
17.06
B
16.82
17.70
C
17.42
18.33
Z18C
A
18.02
18.96
Z20A
B
18.63
19.59
C
19.23
20.22
D
19.72
20.72
Z20D
A
20.15
21.20
Z22A
B
20.64
21.71
C
21.08
22.17
D
21.52
22.63
Z22C
A
22.05
23.18
Z24A
B
22.61
23.77
C
23.12
24.31
D
23.63
24.85
Z24D
A
24.26
25.52
Z27A
B
24.97
26.26
C
25.63
26.95
D
26.29
27.64
Z27D
A
26.99
28.39
Z30A
B
27.70
29.13
C
28.36
29.82
D
29.02
30.51
Z30D
A
29.68
31.22
Z33A
B
30.32
31.88
C
30.90
32.50
D
31.49
33.11
Z33D
A
32.14
33.79
Z36A
B
32.79
34.49
C
33.40
35.13
D
34.01
35.77
Z36D
A
34.68
36.47
Z39A
B
35.36
37.19
C
36.00
37.85
D
Z15A
5
11
0.2
5
40
0.5
110
Z15B
Z15C
Z16A
5
12
0.2
5
40
0.5
150
Z16B
Z16C
Z18A
5
5
5
5
5
5
5
5
13
15
17
19
21
23
25
27
0.2
0.2
0.2
0.2
0.2
0.2
0.2
0.2
5
5
5
5
5
5
5
5
45
55
30
35
45
55
65
75
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
150
200
200
200
250
250
250
250
5
30
0.2
5
85
0.5
250
Z18B
Z20B
Z20C
Z22B
Z22C
Z24B
Z24C
Z27B
Z27C
Z30B
Z30C
Z33B
Z33C
Z36B
Z36C
Z39B
Z39C
36.63
38.52
GLZJ 43
40.00
45.00
5
33
0.2
5
90
--
--
Z43
GLZJ 47
44.00
49.00
5
36
0.2
5
90
--
--
Z47
GLZJ 51
48.00
54.00
5
39
0.2
5
110
--
--
Z51
GLZJ 56
53.00
60.00
5
43
0.2
5
110
--
--
Z56
STAD-SEP.14.2004
Z39D
PAGE . 3
1.3
VZtn – RelativeVoltageChange
500
400
300
l
l
200
100
0
5
10
TK VZ =10 x 10–4/K
8 x 10–4/K
6 x 10–4/K
1.1
4 x 10–4/K
2 x 10–4/K
0
1.0
–2 x 10–4/K
–4 x 10–4/K
0.9
0.8
–60
20
15
l – Lead Length ( mm )
500
400
300
200
100
0
40
80
120
160
200
Tamb – Ambient Temperature(°C )
95 9602
60
120
180
240
Fig. 4 Typical Change of Working Voltage vs. Junction
Temperature
600
0
0
Tj – Junction Temperature (°C )
95 9599
Fig. 1 Thermal Resistance vs. Lead Length
Ptot –Total Power Dissipation ( mW)
1.2
TL=constant
0
95 9611
15
10
5
I Z=5mA
0
–5
0
10
20
30
40
50
V Z – Z-Voltage ( V )
95 9600
Fig. 2 Total Power Dissipation vs. Ambient Temperature
Fig. 5 Temperature Coefficient of Vz vs. Z-Voltage
1000
200
CD – Diode Capacitance ( pF )
VZ –VoltageChange( mV )
V Ztn=V Zt/V Z(25°C)
TK VZ –Temperature Coefficient of VZ ( 10–4 /K)
RthJA –Therm.Resist.Junction/ Ambient ( K/W)
Typical Characteristics (Tamb = 25 °C unless otherwise specified)
Tj =25°C
100
I Z=5mA
10
150
V R=2V
Tj =25°C
100
1
50
0
0
95 9598
5
10
15
20
25
V Z – Z-Voltage ( V )
Fig. 3 Typical Change of Working Voltage under Operating
Conditions at Tamb=25°C
STAD-SEP.14.2004
0
95 9601
5
10
15
20
25
V Z – Z-Voltage ( V )
Fig. 6 Diode Capacitance vs. Z-Voltage
PAGE . 4
50
10
40
IZ – Z-Current ( mA)
I F – Forward Current ( mA)
100
Tj =25°C
1
0.1
30
20
10
0.01
0
0.001
0
0.2
0.4
0.6
0.8
15
1.0
V F – Forward Voltage ( V )
95 9605
r Z – Differential Z-Resistance ( Ω )
IZ – Z-Current ( mA)
25
Ptot=500mW
Tamb=25°C
60
40
20
1000
I Z=1mA
100
0
5mA
10 10mA
Tj =25°C
1
0
4
8
12
16
20
0
V Z – Z-Voltage ( V )
95 9604
35
30
V Z – Z-Voltage ( V )
Fig. 9 Z-Current vs. Z-Voltage
100
80
20
95 9607
Fig. 7 Forward Current vs. Forward Voltage
5
10
15
20
25
V Z – Z-Voltage ( V )
95 9606
Fig. 8 Z-Current vs. Z-Voltage
Zthp –ThermalResistancefor PulseCond.(K/W)
Ptot=500mW
Tamb=25°C
Fig. 10 Differential Z-Resistance vs. Z-Voltage
1000
tp/T=0.5
100
tp/T=0.2
Single Pulse
10
RthJA=300K/W
T=Tjmax–Tamb
tp/T=0.01
tp/T=0.1
tp/T=0.02
tp/T=0.05
1
10–1
95 9603
i ZM =(–VZ+(V Z2+4rzj x T/Zthp)1/2)/(2rzj)
100
101
102
tp – Pulse Length ( ms )
Fig. 11 Thermal Response
STAD-SEP.14.2004
PAGE . 5