123 SAL-A Datasheet

End of Life. Last Available Purchase Date is 30-December-2015
123 SAL-A
www.vishay.com
Vishay BCcomponents
Aluminum Capacitors
Solid Axial
FEATURES
123
SAL-A
128
SAL-RPM
Radial higher
CV/volume
Fig. 1
QUICK REFERENCE DATA
DESCRIPTION
VALUE
Maximum case size 
(Ø D x L in mm)
6.7 x 15.3 to 12.9 x 32.0
Rated capacitance range
(E6 series), CR
Tolerance on CR
6.3 V to 40 V
Category temperature range
- 55 °C to + 125 °C
Useable temperature range
- 80 °C to + 200 °C
Endurance test at 155 °C
and 125 °C
5000 h and 8000 h
Useful life at 125 °C
20 000 h
Useful life at 40 °C, IR applied
450 000 h
Shelf life at 0 V, 125 °C
Based on sectional specification
Climatic category IEC 60068
• EDP, telecommunication, industrial high temperature,
automotive, military and space
• Smoothing, filtering, buffering, timing
• For power supplies, DC/DC converters
MARKING
500 h
IEC 60384-4/EN130300
55/125/56
Note
* This datasheet provides information about parts that are
RoHS-compliant and / or parts that are non-RoHS-compliant. For
example, parts with lead (Pb) terminations are not RoHS-compliant.
Please see the information / tables in this datasheet for details.
APPLICATIONS
1.0 μF to 1000 μF
± 20 %; ± 10 % on request
Rated voltage range, UR
• Polarized aluminum electrolytic capacitors,
solid electrolyte MnO2
Available
• Axial leads, aluminum case, ceramic seal, blue
insulation sleeve
Available
• SAL-A: standard version
• SAL-AG: epoxy filled shock-proof version up to 10 000 g
• Extremely long useful life: 20 000 h at 125 °C
• Extended high temperature range up to 200 °C
• Excellent low temperature impedance and ESR behavior
• Charge and discharge proof, application with
0  resistance allowed
• Reverse DC voltage up to 0.3 x UR allowed
• AC voltage up to 0.8 x UR allowed
• Advanced technology to achieve high reliability and high
stability
• Material categorization: for definitions of compliance
please see www.vishay.com/doc?99912
The capacitors are marked (where possible) with the
following information:
• Rated capacitance (in μF)
• Tolerance code on rated capacitance, code letter in
accordance with IEC 60062 (M = ± 20 %, K = ± 10 %)
• Rated voltage (in V) at corresponding maximum
temperature
• Date code in accordance with IEC 60062
• Name of manufacturer
• Code for factory of origin
• Band to indicate the negative terminal
• “+” sign to identify the positive terminal
• Series number
SELECTION CHART FOR CR, UR, AND RELEVANT MAXIMUM CASE SIZES (Ø D x L in mm)
CR
(μF)
1.0
1.5
2.2
3.3
4.7
6.8
10
15
Revision: 14-Aug-15
6.3
10
6.3
-
10
-
UR (V) AT Tamb = 85 °C
16
25
UC (V) AT Tamb = 125 °C
16
25
6.7 x 15.3
6.7 x 15.3
6.7 x 15.3
6.7 x 15.3
35
40
25
6.7 x 15.3
6.7 x 15.3
6.7 x 15.3
6.7 x 15.3
6.7 x 15.3
6.7 x 15.3
7.6 x 20.4
7.6 x 20.4
25
6.7 x 15.3
6.7 x 15.3
6.7 x 15.3
6.7 x 15.3
7.6 x 20.4
7.6 x 20.4
Document Number: 28355
1
For technical questions, contact: [email protected]
THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT
ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000
End of Life. Last Available Purchase Date is 30-December-2015
123 SAL-A
www.vishay.com
Vishay BCcomponents
SELECTION CHART FOR CR, UR, AND RELEVANT MAXIMUM CASE SIZES (Ø D x L in mm)
6.3
10
6.3
6.7 x 15.3
6.7 x 15.3
7.6 x 20.4
9.4 x 23.3
10.3 x 32.0
12.9 x 32.0
10
6.7 x 15.3
6.7 x 15.3
7.6 x 20.4
7.6 x 20.4
9.4 x 23.3
9.4 x 23.3
10.3 x 32.0
10.3 x 32.0
12.9 x 32.0
12.9 x 32.0
CR
(μF)
22
33
47
68
100
150
220
330
470
680
1000
UR (V) AT Tamb = 85 °C
16
25
UC (V) AT Tamb = 125 °C
16
25
6.7 x 15.3
7.6 x 20.4
7.6 x 20.4
7.6 x 20.4
7.6 x 20.4
7.6 x 20.4
7.6 x 20.4
9.4 x 23.3
9.4 x 23.3
9.4 x 23.3
9.4 x 23.3
10.3 x 32.0
10.3 x 32.0
12.9 x 32.0
10.3 x 32.0
12.9 x 32.0
-
35
40
25
7.6 x 20.4
9.4 x 23.3
9.4 x 23.3
10.3 x 32.0
12.9 x 32.0
12.9 x 32.0
-
25
9.4 x 23.3
9.4 x 23.3
10.3 x 32.0
10.3 x 32.0
12.9 x 32.0
-
DIMENSIONS in millimeters AND AVAILABLE FORMS
ØD
Ød
Lmax.
F
BA: taped in box (ammopack)
BR: taped on reel
73
Fig. 2 - Forms: BA and BR
Table 1
DIMENSIONS in millimeters, MASS AND PACKAGING QUANTITIES
CASE
MAXIMUM SIZE Ø D x L (1)
6.7 x 15.3
7.6 x 20.4
9.4 x 23.3
10.3 x 32.0
12.9 x 32.0
CODE
1
2A
4
5
6
Fmax.
Ød
MASS (2)
(g)
20.0
22.5
25.0
35.0
35.0
0.6
0.6
0.6
0.8
0.8
 1.05
 1.55
 2.60
 4.20
 7.00
PACKAGING QUANTITIES
FORM BA
FORM BR
100
800
100
800
100
500
100
500
100
400
Notes
(1) For epoxy-filled versions add 1 mm to stated L
max..
(2) Add 10 % for SAL-AG epoxy-filled versions.
• Detailed tape dimensions see www.vishay.com/doc?28361.
CARDBOARD BOX DIMENSIONS, L x W x H (mm)
SOLID TYPES FORM BA
6.7 x 15.3
7.6 x 20.4
9.4 x 23.3
10.3 x 32.0
12.9 x 32.0
110 x 95 x 70
110 x 95 x 70
110 x 95 x 85
160 x 95 x 85
160 x 95 x 120
SOLID TYPES FORM BR
all
Revision: 14-Aug-15
370 x 370 x 115
Document Number: 28355
2
For technical questions, contact: [email protected]
THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT
ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000
End of Life. Last Available Purchase Date is 30-December-2015
123 SAL-A
www.vishay.com
ELECTRICAL DATA
SYMBOL
CR
IR
IL5
tan 
ESR
Z
DESCRIPTION
Rated capacitance at 100 Hz
Max. RMS ripple current,
no necessary DC voltage applied
Max. leakage current after 5 min at UR
Max. dissipation factor at 100 Hz
Max./typ. equivalent series resistance at 100 Hz
Max. impedance at 100 kHz
Note
• Unless otherwise specified, all electrical values in Table 2 apply
at Tamb = 20 to 25 °C, P = 86 to 106 kPa, RH = 45 to 75 %.
Vishay BCcomponents
ORDERING EXAMPLE
Electrolytic capacitors 123 series
10 μF/16 V; ± 20 %
Maximum case size: Ø 6.7 x 15.3 mm; form BR
for lead (Pb)-free:
Ordering code: MAL2 123 25109 E3 
Former 12NC: 2281 123 25109
for non lead (Pb)-free:
Ordering code: MAL2 123 25109
Former 12NC: 2222 123 25109
Table 2
ELECTRICAL DATA AND ORDERING INFORMATION for 123 series
UC UR
(V) (V)
6.3 6.3
10
10
16
16
25
25
ORDERING CODE
MAL2123.....E3 LEAD (Pb)-FREE
MAL2123 ..... NON LEAD (Pb)-FREE
MAX.
IR
IR
IR
MAX.
TYP.
IL5
CR
Z
CASE
SAL-AG (1)
tan 
100 Hz 10 kHz 100 kHz
ESR
ESR
SAL-AG (1)
SAL-A
SAL-A
100 Hz
SIZE
FORM
125 °C 85 °C
40 °C 5 min 100 Hz 100 Hz 100 Hz 100 kHz FORM FORM
FORM
()
(μF)
ØDxL
(μA)
BA
(mA)
(mA)
(mA)
()
()
BA
BR
BA
(mm)
TOL.
TOL.
TOL.
TOL.
±
10
%
± 20 % ± 20 %
± 20 %
LEVEL S
47
6.7 x 15.3
58
440
640
15
0.18
7.6
3.0
1.2
13479 23479
83479
63479
68
6.7 x 15.3
83
520
760
21
0.18
5.3
2.6
1.2
13689 23689
83689
63689
150
7.6 x 20.4
160
870
1270
47
0.18
2.4
1.5
1.0
13151 23151
83151
63151
330
9.4 x 23.3
330
1470
2140
104
0.18
1.1
0.55
0.4
13331 23331
83331
63331
680
10.3 x 32.0
680
2340
3410
214
0.18
0.55
0.28
0.3
13681 23681
83681
63681
1000 12.9 x 32.0
940
3180
4640
315
0.18
0.36
0.19
0.2
13102 23102
83102
63102
33
6.7 x 15.3
63
360
530
17
0.18
11
3.8
1.2
14339 24339
84339
64339
47
6.7 x 15.3
83
440
640
24
0.18
7.6
4.0
1.2
14479 24479
84479
64479
68
7.6 x 20.4
110
590
850
34
0.18
5.3
2.5
1.0
14689 24689
84689
64689
100
7.6 x 20.4
160
710
1040
50
0.18
3.6
1.8
1.0
14101 24101
84101
64101
150
9.4 x 23.3
240
990
1450
75
0.18
2.4
0.9
0.4
14151 24151
84151
64151
220
9.4 x 23.3
350
1180
1720
110
0.18
1.7
0.6
0.4
14221 24221
84221
64221
330
10.3 x 32.0
490
1650
2410
165
0.18
1.1
0.45
0.3
14331 24331
84331
64331
470
10.3 x 32.0
570
1940
2830
235
0.18
0.8
0.35
0.3
14471 24471
84471
64471
680
12.9 x 32.0
760
2580
3750
340
0.18
0.55
0.25
0.2
14681 24681
84681
64681
1000 12.9 x 32.0 1000
3380
4920
500
0.18
0.36
0.18
0.2
14102 24102
84102
64102
10
6.7 x 15.3
31
230
330
16
0.14
28
8.0
2.5
15109 25109
85109
65109
15
6.7 x 15.3
47
280
400
24
0.14
19
5.5
2.5
15159 25159
85159
65159
22
6.7 x 15.3
63
340
490
35
0.14
13
5.5
2.5
15229 25229
85229
65229
33
7.6 x 20.4
89
470
680
55
0.14
8.4
3.0
2.0
15339 25339
85339
65339
47
7.6 x 20.4
120
560
810
75
0.14
5.9
2.6
2.0
15479 25479
85479
65479
68
7.6 x 20.4
180
670
970
110
0.14
4.1
2.5
2.0
15689 25689
85689
65689
100
9.4 x 23.3
260
920
1340
160
0.14
2.8
1.5
0.8
15101 25101
85101
65101
150
9.4 x 23.3
310
1060
1550
240
0.16
2.1
0.7
0.8
15151 25151
85151
65151
220
10.3 x 32.0
420
1420
2060
350
0.16
1.5
0.55
0.6
15221 25221
85221
65221
330
10.3 x 32.0
510
1740
2530
500
0.16
1.0
0.35
0.6
15331 25331
85331
65331
470
12.9 x 32.0
680
2280
3330
750
0.16
0.7
0.25
0.4
15471 25471
85471
65471
10
6.7 x 15.3
43
230
330
25
0.14
28
13.0
5
16109 26109
86109
66109
15
6.7 x 15.3
60
280
400
35
0.14
19
10.0
5.0
16159 26159
86159
66159
22
7.6 x 20.4
88
370
550
55
0.14
13
7
2.5
16229 26229
86229
66229
33
7.6 x 20.4
130
470
680
85
0.14
8.4
5
2.5
16339 26339
86339
66339
47
7.6 x 20.4
160
560
810
100
0.14
5.9
3.5
2.5
16479 26479
86479
66479
68
9.4 x 23.3
230
760
1110
170
0.14
4.1
1.8
1.0
16689 26689
86689
66689
100
9.4 x 23.3
250
860
1250
250
0.16
3.2
1.0
1.0
16101 26101
86101
66101
150
10.3 x 32.0
350
1200
1740
400
0.16
2.1
1.2
0.8
16151 26151
86151
66151
220
12.9 x 32.0
460
1560
2270
550
0.16
1.5
0.85
0.6
16221 26221
86221
66221
Revision: 14-Aug-15
Document Number: 28355
3
For technical questions, contact: [email protected]
THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT
ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000
End of Life. Last Available Purchase Date is 30-December-2015
123 SAL-A
www.vishay.com
Vishay BCcomponents
ELECTRICAL DATA AND ORDERING INFORMATION for 123 series
ORDERING CODE
MAL2123.....E3 LEAD (Pb)-FREE
MAL2123 ..... NON LEAD (Pb)-FREE
MAX.
IR
IR
IR
MAX.
TYP.
CR
IL5
Z
CASE
SAL-AG (1)
tan 
UC UR
100 Hz 10 kHz 100 kHz
ESR
ESR
SAL-A
SAL-A
SAL-AG (1)
SIZE
FORM
(V) (V) 100 Hz
125 °C 85 °C
40 °C 5 min 100 Hz 100 Hz 100 Hz 100 kHz FORM FORM
FORM
()
(μF)
ØDxL
(μA)
BA
(mA)
(mA)
(mA)
()
()
BA
BR
BA
(mm)
TOL.
TOL.
TOL.
TOL.
±
10
%
± 20 % ± 20 %
± 20 %
LEVEL S
1.0
6.7 x 15.3
4
55
80
5
0.12
240
105
16.5
10108 20108
80108
60108
1.5
6.7 x 15.3
7
68
98
5
0.12
160
40.60
11.0
10158 20158
80158
60158
2.2
6.7 x 15.3
10
82
120
5
0.12
109
30
7.5
10228 20228
80228
60228
3.3
6.7 x 15.3
14
100
150
7
0.12
73
28
7.5
10338 20338
80338
60338
4.7
6.7 x 15.3
20
120
170
10
0.12
51
20
7.5
10478 20478
80478
60478
6.8
6.7 x 15.3
27
140
210
15
0.12
35
16
7.5
10688 20688
80688
60688
10
7.6 x 20.4
37
200
280
20
0.12
24
10
2.5
10109 20109
80109
60109
25 35
15
7.6 x 20.4
53
240
350
30
0.12
16
8
2.5
10159 20159
80159
60159
22
7.6 x 20.4
78
290
420
45
0.12
11
7
2.5
10229 20229
80229
60229
33
9.4 x 23.3
120
410
590
65
0.12
7.2
3
1.0
10339 20339
80339
60339
47
9.4 x 23.3
140
480
700
95
0.12
5.1
2.9
1.0
10479 20479
80479
60479
68
10.3 x 32.0
170
570
820
135
0.16
4.7
2.1
0.8
10689 20689
80689
60689
100
12.9 x 32.0
220
760
1100
200
0.16
3.2
1.7
0.6
10101 20101
80101
60101
150
12.9 x 32.0
290
990
1440
300
0.16
2.1
1.0
0.6
10151 20151
80151
60151
2.2
6.7 x 15.3
11
82
120
9
0.12
109
38
7.5
17228 27228
87228
67228
3.3
6.7 x 15.3
16
100
150
13
0.12
73
25
7.5
17338 27338
87338
67338
4.7
6.7 x 15.3
22
120
170
19
0.12
51
20
7.5
17478 27478
87478
67478
6.8
6.7 x 15.3
28
140
210
27
0.12
35
15
7.5
17688 27688
87688
67688
10
7.6 x 20.4
41
200
280
40
0.12
24
11
2.5
17109 27109
87109
67109
15
7.6 x 20.4
61
240
350
60
0.12
16
7
2.5
17159 27159
87159
67159
25 40
22
9.4 x 23.3
89
330
480
90
0.12
11
4
1.5
17229 27229
87229
67229
33
9.4 x 23.3
120
410
590
130
0.12
7.2
2.9
1.0
17339 27339
87339
67339
47
10.3 x 32.0
160
540
790
190
0.12
5.1
2.7
1.0
17479 27479
87479
67479
68
10.3 x 32.0
170
570
820
270
0.16
4.7
2.3
0.8
17689 27689
87689
67689
100
12.9 x 32.0
220
760
1100
400
0.16
3.2
1.6
0.6
17101 27101
87101
67101
Note
(1) SAL-AG types are epoxy-filled.
ADDITIONAL ELECTRICAL DATA
PARAMETER
Voltage
Surge voltage
Reverse voltage
Maximum peak AC voltage,
reverse voltage applied
Maximum peak AC voltage,
without reverse voltage applied
CONDITIONS
VALUE
Us  1.15 x UR
Urev < 0.3 x UR
2V
Tamb  85 °C at:
f  0.1 Hz
0.1 Hz < f  1 Hz
1 Hz < f  10 Hz
10 Hz < f  50 Hz
f > 50 Hz
85 °C < Tamb  125 °C at:
f  0.1 Hz
0.1 Hz < f  1 Hz
1 Hz < f  10 Hz
10 Hz < f  50 Hz
f > 50 Hz
0.30 x UR
0.45 x UR
0.60 x UR
0.65 x UR
0.80 x UR
0.15 x UR
0.22 x UR
0.30 x UR
0.32 x UR
0.40 x UR
Current
Maximum leakage current
After 5 min at UR and Tamb = 25 °C
IL5  0.05 CR x UR or 2 μA, whichever is greater;
see Table 2
Typical leakage current
After 15 s at UR and Tamb = 25 °C:
UR = 6.3 V to 16 V
UR = 25 V to 40 V
0.2 x value stated in Table 2
0.1 x value stated in Table 2
Revision: 14-Aug-15
Document Number: 28355
4
For technical questions, contact: [email protected]
THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT
ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000
End of Life. Last Available Purchase Date is 30-December-2015
123 SAL-A
www.vishay.com
Vishay BCcomponents
VOLTAGE
RIPPLE CURRENT (IR)
40
(1)
35
(2)
(1)
UC = 125 °C
UC = 175 °C
(2)
Tamb
PARAMETER
25 °C 40 °C 65 °C 85 °C 105 °C 125 °C
UR
(V)
IR multiplier
25
1.1
1.0
0.88
0.75
0.59
0.37
Notes
(1) Applying the maximum RMS ripple current given in Table 2
will cause a device temperature of 138 °C.
(2) The 100 kHz values in Table 2 for other temperatures are to
be calculated with the above IR multipliers.
16
10
6.3
4
0
- 50
0
50
85
100
125
150 175
Tamb (°C)
Fig. 3 - Maximum permissible voltage up to 175 °C
LEAKAGE CURRENT
10 2
10
reverse voltage
I
I01
I
I 02
10
1
1
10
-1
I01 = leakage current during continuous operation
at UR and Tamb = 25 °C
- 50
0
50
150
100
10-1
I02 = leakage current at UR at a
discrete constant temperature
- 0.4
0
0.4
Tamb (°C)
Fig. 5 - Typical multiplier of leakage current as a function of U/UR
DISSIPATION FACTOR (tan )
1.1
standard deviation σ
C
C0
1.0
0.9
2.4
tan δ
tan δ0
2.0
Typical tan δ at 100 Hz and Tamb = 25 °C:
0.6 x value stated in Table 2
standard deviation σ
CAPACITANCE (C)
1.6
1.2
0.8
0.05
σ
0.4
0.8
C0 = capacitance at 25 °C and 100 Hz
0
40
80
0
120
160
200
Tamb (°C)
Fig. 6 - Typical multiplier of capacitance as a function of
ambient temperature
Revision: 14-Aug-15
0.25
0
σ
0
- 40
0.8
UR
Fig. 4 - Typical multiplier of leakage current as a function of
ambient temperature
- 80
U
- 80
- 40
0
40
80
120
160
200
Tamb (°C)
Fig. 7 - Typical multiplier of dissipation factor as a function of
ambient temperature
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MAXIMUM POWER DISSIPATION
MAXIMUM CASE SIZE
ØDxL
(mm)
Pmax. = P125
(W)
6.7 x 15.3
0.13
7.6 x 20.4
0.16
9.4 x 23.3
0.21
10.3 x 32.0
0.26
12.9 x 32.0
0.32
EQUIVALENT SERIES INDUCTANCE (ESL), f = 10 MHz
MAXIMUM CASE SIZE
ØDxL
(mm)
PITCH
(mm)
MAX. ESL
(nH)
TYP. ESL
(nH)
6.7 x 15.3
20.3
30
15 to 23
7.6 x 20.4
25.4
30
16 to 24
9.4 x 23.3
27.9
35
20 to 27
10.3 x 32.0
35.6
40
26 to 33
12.9 x 32.0
35.6
55
32 to 49
IMPEDANCE (Z)
Typical impedance at 100 kHz and Tamb = 25 °C: 0.5 x value stated in Table 2.
3.5
Z
1
Z0
3.0
2
3
2.5
1
2.0
2
3
- 55 °C
1.5
- 25 °C
+ 25 °C
1.0
3
+ 85 °C
0.5
2
1
3
+ 175 °C
2
1
0
10
10 2
10 3
10 4
10 5
1
1
4
7
10
10 6
f (Hz)
10 7
10
3
standard deviation σ (%)
Curve 1: Case Ø D x L = 6.7 mm x 15.3 mm and 7.6 mm x 20.4 mm; 16 V to 40 V
Curve 2: Case Ø D x L = 6.7 mm x 15.3 mm and 7.6 mm x 20.4 mm; 6.3 V to 10 V
Curve 3: Case Ø D x L = 9.4 mm x 32.0 mm, 10.3 mm x 32.0 mm and 12.9 mm x 32.0 mm
Z0 = Initial impedance value at any frequency and Tamb = 25 °C
Fig. 8 - Typical multiplier of impedance as a function of frequency at different ambient temperatures
Revision: 14-Aug-15
Document Number: 28355
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IMPEDANCE (Z)
103
104
Z
(Ω)
Curve 1: 10 µF, 16 V
Curve 2: 15 µF, 16 V
Curve 3: 22 µF, 16 V
Curve 4: 33 µF, 10 V
Curve 5: 47 µF, 6.3 and 10 V
Curve 6: 68 µF, 6.3 V
1
2
3
4
5
6
102
Z
(Ω)
102
1
10
Case Ø D x L = 6.7 x 15.3 mm;
UR = 25 to 40 V
Case Ø D x L = 6.7 x 15.3 mm; UR = 6.3 to 16 V
10-1
1
2
3
4
5
6
103
10
Curve 1: 2.2 µF, 35 and 40 V
Curve 2: 3.3 µF, 40 V
Curve 3: 4.7 µF, 35 and 40 V
Curve 4: 6.8 µF, 35 and 40 V
Curve 5: 10 µF, 25 V
Curve 6: 15 µF, 25 V
1
102
10
103
104
105
106 f (Hz) 107
10
102
103
104
105
Tamb = 25 °C
Tamb = 25 °C
Fig. 9 - Typical impedance as a function of frequency
Fig. 10 - Typical impedance as a function of frequency
103
103
Curve 1: 33 µF, 16 V
Curve 2: 47 µF, 16 V
Curve 3: 68 µF, 10 V
Curve 4: 100 µF, 6.3 and 10 V
Curve 5: 150 µF, 6.3 V
Z
(Ω)
102
1
2
3
4
5
10
Z
(Ω)
Curve 1: 10 µF, 35 and 40 V
Curve 2: 15 µF, 35 and 40 V
Curve 3: 22 µF, 25 and 40 V
Curve 4: 33 µF, 25 V
Curve 5: 47 µF, 25 V
Curve 6: 68 µF, 16 V
1
2
3
4
5
6
102
10
1
1
10-1
Case Ø D x L = 6.7 x 20.4 mm
UR = 6.3 to 16 V
10
10
2
3
10
10-1
10
4
10
5
6
7
10 f (Hz) 10
Case Ø D x L = 6.7 x 20.4 mm; UR = 16 to 40 V
10
102
103
104
105
Tamb = 25 °C
Fig. 12 - Typical impedance as a function of frequency
103
102
Curve 1: 150V, 10 V
Curve 2: 220 V, 10V
Curve 3: 330 V, 6.3 V
Z
(Ω)
10
1
2
3
4
5
6
10
1
-1
Curve 1: 22 µF, 40 V
Curve 2: 33 µF, 35 and 40 V
Curve 3: 47 µF, 35 V
Curve 4: 68 µF, 25 V
Curve 5: 100 µF, 16 and 25 V
Curve 6: 150 µF, 16 V
Z
(Ω)
102
1
2
3
1
10
-2
106 f (Hz) 107
Tamb = 25 °C
Fig. 11 - Typical impedance as a function of frequency
10
106 f (Hz) 107
Case Ø D x L = 9.4 x 23.3 mm; UR = 6.3 to 10 V
10
102
103
104
105
10-1
106 f (Hz) 107
Tamb = 25 °C
Fig. 13 - Typical impedance as a function of frequency
Revision: 14-Aug-15
Case Ø D x L = 9.4 x 23.3 mm;
UR = 16 to 40 V
10
102
103
104
105
106 f (Hz) 107
Tamb = 25 °C
Fig. 14 - Typical impedance as a function of frequency
Document Number: 28355
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IMPEDANCE (Z)
102
103
Curve 1: 220 µF, 16 V
Curve 2: 330 µF, 16 V
Curve 3: 330 µF, 10 V
Curve 4: 470 µF, 10 V
Curve 5: 680 µF, 6.3 V
Z
(Ω)
1
2
3
4
5
10
1
Curve 1: 47 V, 40 V
Curve 2: 68 V, 35 and 40 V
Curve 3: 150 V, 25 V
Z
(Ω)
102
1
2
3
10
-1
1
10
10-2
Case Ø D x L = 10.3 x 32.0 mm; UR = 6.3 to 16 V
102
10
103
104
105
10-1
106 f (Hz) 107
Case Ø D x L = 10.3 x 32.0 mm;
UR = 25 to 40 V
102
10
103
104
105
106 f (Hz) 107
Tamb = 25 °C
Tamb = 25 °C
Fig. 15 - Typical impedance as a function of frequency
Fig. 16 - Typical impedance as a function of frequency
102
102
Curve 1: 680 µF, 10 V
Curve 2: 1000 µF, 6.3 V
Curve 3: 1500 µF, 6.3 V
Z
(Ω)
10
Z
(Ω)
1
1
10-1
10-1
10-2
Case Ø D x L = 12.9 x 32.0 mm; UR = 6.3 to 10 V
10 2
1
2
3
4
5
6
10
1
2
3
10 4
103
10-2
Case Ø D x L = 12.9 x 32.0 mm; UR = 10 to 40V
10 2
10 6 f (Hz) 10 7
Tamb = 25 °C
10 5
Curve 1: 100 µF, 35 and 40 V
Curve 2: 150 µF, 35 V
Curve 3: 220 µF, 25 V
Curve 4: 470 µF, 16 V
Curve 5: 680 µF, 16 V
Curve 6: 1000 µF, 10 V
10 4
103
10 6 f (Hz) 10 7
10 5
Tamb = 25 °C
Fig. 17 - Typical impedance as a function of frequency
Fig. 18 - Typical impedance as a function of frequency
EQUIVALENT SERIES RESISTANCE (ESR)
Typical ESR: see Figures 20 to 28; the standard deviation is 20 % of each value.
102
102
Case Ø D x L = 6.7 x 15.3 mm
ESR at 100 Hz
ESR
(Ω)
10
1
Case Ø D x L = 7.6 x 20.4 mm
ESR at 100 Hz
ESR
(Ω)
10
1
3
2
1
10-1
4
5
Curve 1: 10 mF, 25 V; 6.8 mF, 35 and 40 V
Curve 2: 10 mF, 16 V
Curve 3: 22 mF, 16 V
Curve 4: 33 mF, 10 V
Curve 5: 47 mF, 6.3 and 10 V; 68 mF, 6.3 V
- 80
- 40
0
40
80
1
10-1
120
160
200
Tamb (°C)
Fig. 19 - Typical ESR as a function of ambient temperature
Revision: 14-Aug-15
2
3
4
5
Curve 1: 10 µF, 35 and 40 V
Curve 2: 33 µF, 25 V
Curve 3: 47 µF, 25 V
Curve 4: 68 µF, 10 V; 150 µF, 6.3 V
- 80
- 40
0
40
80
120
160
200
Tamb (°C)
Fig. 20 - Typical ESR as a function of ambient temperature
Document Number: 28355
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EQUIVALENT SERIES RESISTANCE (ESR)
102
102
Curve 1: 33 µF, 35 and 40 V
Curve 2: 220 µF, 10 V; 330 µF, 6.3 V
ESR
(Ω)
Case Ø D x L = 10.3 x 32.0 mm
ESR at 100 Hz
ESR
(Ω)
Curve 1: 68 µF, 35 and 40 V
Curve 2: 150 µF, 25 V
Curve 3: 330 µF, 10 V
Curve 4: 470 µF, 10 V
10
10
1
1
1
1
2
2
Case Ø D x L = 9.4 x 23.3 mm
10-1
- 40
- 80
0
40
ESR at 100 Hz
80
120
160
102
ESR
(Ω)
10
Curve 1: 100 µF, 35 and 40 V
Curve 2: 150 µF, 35 V
Curve 3: 220 µF, 25 V
Curve 4: 470 µF, 16 V
Curve 5: 680 µF, 10 V;
1000 µF, 6.3 V
- 40
- 80
200
Tamb (°C)
Fig. 21 - Typical ESR as a function of ambient temperature
Case Ø D x L = 12.9 x 32.0 mm
ESR at 100 Hz
3
4
10-1
0
40
80
120
160
200
Tamb (°C)
Fig. 22 - Typical ESR as a function of ambient temperature
103
ESR
(Ω)
Curve 1: 10 µF, 25 V; 6.8 µF, 35 and 40 V
Curve 2: 10 µF, 16 V
Curve 3: 22 µF, 16 V
Curve 4: 33 µF, 10 V
Curve 5: 47 µF, 6.3 and 10 V; 68 µF, 6.3 V
1
2
3
102
4
5
10
1
10-1
- 40
- 80
0
40
80
120
160
1
2
3
4
1
5
10-1
Case Ø D x L = 6.7 x 15.3 mm
1
200
Tamb (°C)
Fig. 23 - Typical ESR as a function of ambient temperature
10
10 2
10 3
10 4
10 5
10 6
f (Hz)
Tamb = 25 °C
Fig. 25 - Typical ESR as a function of frequency
102
103
ESR
(Ω)
Curve 1: 10 µF, 35 and 40 V
Curve 2: 33 µF, 25 V
Curve 3: 47 µF, 25 V
Curve 4: 68 µF, 10 V; 150 µF, 6.3 V
Curve 5: 100 µF, 10 V
1
102
2
3
4
5
10
Curve 1: 33 µF, 35 and 40 V
Curve 2: 220 µF, 10 V; 330 µF, 6.3 V
ESR
(Ω)
10
1
1
1
2
10-1
Case Ø D x L = 6.7 x 20.4 mm
10-1
1
10
10 2
10 3
10 4
10 5
10 6
f (Hz)
Tamb = 25 °C
Fig. 24 - Typical ESR as a function of frequency
Revision: 14-Aug-15
Case Ø D x L = 9.4 x 23.3 mm
10-2
1
10
10 2
10 3
10 4
10 5
10 6
f (Hz)
Tamb = 25 °C
Fig. 26 - Typical ESR as a function of frequency
Document Number: 28355
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EQUIVALENT SERIES RESISTANCE (ESR)
102
102
ESR
(Ω)
Curve 1: 68 µF, 35 and 40 V
Curve 2: 150 µF, 25 V
Curve 3: 330 µF, 10 V
Curve 4: 470 µF, 10 V
1
10
2
ESR
(Ω)
10
1
2
3
4
1
5
Curve 1: 100 µF, 35 and 40 V
Curve 2: 150 µF, 35 V
Curve 3: 220 µF, 25 V
Curve 4: 470 µF, 16 V
Curve 5: 680 µF, 10 V; 1000 µF, 6.3 V
3
4
1
10-1
10-1
Case Ø D x L = 9.4 x 23.3 mm
10-2
1
10 2
10
10 3
ESR at 100 Hz
10 4
10 5
10 6
f (Hz)
Fig. 27 - Typical ESR as a function of ambient temperature
ESR at 100 Hz
Case Ø D x L = 9.4 x 23.3 mm
10-2
1
10
10 2
10 3
10 4
10 5
10 6
f (Hz)
Fig. 28 - Typical ESR as a function of ambient temperature
Table 3
TEST PROCEDURES AND REQUIREMENTS
TEST
NAME OF TEST
REFERENCE
PROCEDURE
(quick reference)
Endurance
IEC 60384-4/
EN130300
subclause 4.13
Tamb = 125 °C;
UR = 6.3 V to 25 V with UR applied;
UR = 35 V and 40 V with UC applied;
10 000 h
Useful life
CECC 30302
subclause 1.8.1
Tamb = 125 °C; IR applied and
UR = 6.3 V to 25 V with UR applied;
UR = 35 V and 40 V with UC applied;
20 000 h
Shelf life
(storage at high
temperature)
IEC 60384-4/
EN130300
subclause 4.17
Tamb = 125 °C; no voltage applied;
500 h
Charge and
discharge
IEC 60384-4-2
subclause 9.21
106 cycles without series resistance:
0.5 s to UR;
0.5 s to ground
Shock
IEC 60068-2-27
test Ea
Half-sine or saw tooth pulse shape; 50 g; 11 ms; 
3 successive shocks in each direction of
3 mutually perpendicular axes;
no voltage applied
Severe rapid change
of temperature
Solvent resistance
Passive flammability
Revision: 14-Aug-15
100 cycles of 1 h duration, each with
30 min at - 40 °C and + 125 °C
REQUIREMENTS
C/C: ± 10 %
tan   1.2 x spec. limit
Z  1.2 x spec. limit
IL5  spec. limit
C/C: ± 15 %
tan   1.5 x spec. limit
Z  1.5 x spec. limit
IL5  spec. limit
no short or open circuit, 
no visible damage
total failure percentage: < 1 %
C/C: ± 10 %
tan   1.2 x spec. limit
IL5  1 x spec. limit
C/C: ± 5 %
no short or open circuit, 
no visible damage
no intermittent contacts
no breakdown
no open circuiting
no mechanical damage
C/C: ± 5 %
tan   1.2 x spec. limit
Z  1.2 x spec. limit
IL5  1.5 x spec. limit
C/C: ± 25 %
tan   1.5 x spec. limit
Z  2.0 x spec. limit
IL5  1 x spec.limit
IEC 60068-2-45,
test XA
IEC 60653
Immersion:
5 min ± 0.5 min with or without ultrasonic 
at 55 °C ± 5 °C
Solvents: demineralized water and/or calgonite
solution (20 g/l)
Visual appearance not affected
IEC 60695-2-2
Capacitor mounted to a vertical printed-circuit
board, one flame on capacitor body; 
Tamb = 20 °C to 25 °C;
test duration = 20 s
After removing the test flame from the
capacitor, the capacitor must not
continue to burn for more than 15 s; 
no burning particles must drop from
the sample
Document Number: 28355
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ADDITIONAL TESTS AND REQUIREMENTS FOR EPOXY-FILLED VERSIONS SAL-AG
2281 123 8.... Form BA ± 10 %, level S, lead (Pb)-free
2222 123 8.... Form BA ± 10 %, level S, non lead (Pb)-free
Table 4
TEST PROCEDURES AND REQUIREMENTS
TEST
PROCEDURE
REQUIREMENTS
Severe vibration tests in accordance with “IEC 60068-2-6” and “MIL STD-202”, method 204, letter E, with the following details and
additions
Method of mounting:
Clamping both body and leads
Severity 1
Frequency range temperature 10 Hz to 3000 Hz;
20 °C to 25 °C
Severity 2
Frequency range temperature 50 Hz to 2000 Hz; 125 °C
Severity 1 and 2
vibration amplitude: 50 g or 3.5 mm, whichever is less
Direction and duration of motion:
Severity 1
1 octave/min; 3 directions (mutually perpendicular);
20 sweeps per direction (total 60 sweeps or 18 h)
Severity 2
1 octave/min; 2 directions (longitudinal and transversal);
3 sweeps per direction (total 6 sweeps or 1 h)
Functioning:
Severity 1
C/C: ± 10 %
tan  1.2 x stated limit
Z  1.4 x stated limit
DC leakage current:  stated limit
no intermittent contacts
no indication of breakdown
no open circuiting
no evidence of mechanical damage
Rated voltage applied
Severity 2
No voltage applied
Typical capability
> 80 g at 10 Hz to 3000 Hz (also at 125 °C)
Severe shock tests in accordance with “IEC 60068-2-27” and “MIL STD-202”, method 213, letter F, with the following details and
additions
Method of mounting
Clamping both body and leads
Pulse shape:
Half-sine or sawtooth
Severity 1
1500 g; 0.5 ms (“MIL STD-202”, method 213, letter F)
Severity 2
3000 g; 0.2 ms
Severity 3
10 000 g; 0.1 ms
Direction and number of shocks:
Severity 1 and 2
3 successive shocks in each direction of 3 mutually
perpendicular axes (total 18 shocks)
Severity 3
1 shock in any direction
Functioning
Rated voltage applied
Revision: 14-Aug-15
C/C: ± 10 %
tan  1.2 x stated limit
Z  1.4 x stated limit
DC leakage current:  stated limit
no intermittent contacts
no indication of breakdown
no open circuiting
no evidence of mechanical damage
Document Number: 28355
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including but not limited to the warranty expressed therein.
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definitions and restrictions defined under Directive 2011/65/EU of The European Parliament and of the Council
of June 8, 2011 on the restriction of the use of certain hazardous substances in electrical and electronic equipment
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Please note that some Vishay documentation may still make reference to RoHS Directive 2002/95/EC. We confirm that
all the products identified as being compliant to Directive 2002/95/EC conform to Directive 2011/65/EU.
Vishay Intertechnology, Inc. hereby certifies that all its products that are identified as Halogen-Free follow Halogen-Free
requirements as per JEDEC JS709A standards. Please note that some Vishay documentation may still make reference
to the IEC 61249-2-21 definition. We confirm that all the products identified as being compliant to IEC 61249-2-21
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Revision: 02-Oct-12
1
Document Number: 91000