1997 Nov 13 1
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
FEATURES
•Polarized aluminium electrolytic
capacitors, solid electrolyte MnO2
•Axial leads, aluminium case,
ceramic seal, blue insulation sleeve
•SAL-A: standard version
•SAL-AG: epoxy filled shock-proof
version up to 10000 g
•Extremely long useful life
20000 hours at 125 °C
•Extended usable temperature
range up to 200 °C
•Excellent low temperature
impedance and ESR behaviour
•Charge and discharge proof,
application with 0 Ω resistance
allowed
•Reverse DC voltage up to 0.3 × UR
allowed
•AC voltage up to 0.8 ×UR allowed
•Advanced technology to achieve
high reliability and high stability.
Fig.1 Component outlines.
handbook, 4 columns
MBB121
handbook, 4 columns
MBG077
SAL RP
122
radial
version
SAL A
123 SAL RPM
128
radial
higher
CV/volume
APPLICATIONS
•EDP, telecommunications,
general industrial, automotive,
military and space
•Smoothing, filtering, buffering,
timing
•For power supplies, DC/DC
converters.
QUICK REFERENCE DATA
DESCRIPTION VALUE
Case size (∅Dmax ×Lmax in mm) 6.7 ×15.3 to 12.9 ×32.0
Rated capacitance range (E6 series), CR1.5 to 1500 µF
Tolerance on CR±20%; ±10% on request
Rated voltage range, UR6.3 to 40 V
Category temperature range −55 to +125 °C
Usable temperature range −80 to +200 °C
Endurance test at 155 and 125 °C 5000 and 8000 hours
Useful life at 125 °C 20000 hours
Useful life at 40 °C, IR applied 450000 hours
Shelf life at 0 V, 125 °C 500 hours
Based on sectional specification IEC 384-4, CECC 30300
Detail specification IEC 384-4-2, CECC 30302
Climatic category IEC 68 55/125/56
1997 Nov 13 2
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Selection chart for CR, UR and relevant maximum case sizes (∅D×L in mm)
Preferred types in bold.
Note
1. Not CECC approved.
MARKING
The capacitors are marked (where possible) with the following information:
•Rated capacitance (in µF)
•Tolerance code on rated capacitance (M = ±20%, K = ±10%, in accordance with
“IEC 62”
)
•Rated voltage (in V) at corresponding maximum temperature
•Date code in accordance with
“IEC 62”
•Name of manufacturer
•Group number (123)
•Code for factory of origin
•Code for basic specification (in accordance with
“IEC 384-4”
•“+” sign to indicate the positive terminal
•A band to identify the negative terminal.
•Not CECC approved.
CR
(µF) UR (V)
6.3 10 16 25 35 40(1)
1.0 −− − −6.7 ×15.3 −
1.5 −− − −6.7 ×15.3 −
2.2 −− − −6.7 ×15.3 6.7 ×15.3
3.3 −− − −6.7 ×15.3 6.7 ×15.3
4.7 −− − −6.7 ×15.3 6.7 ×15.3
6.8 −− − −6.7 ×15.3 6.7 ×15.3
10 −−6.7 ×15.3 6.7 ×15.3 7.6 ×20.4 7.6 ×20.4
15 −−6.7 ×15.3 6.7 ×15.3 7.6 ×20.4 7.6 ×20.4
22 −−6.7 ×15.3 7.6 ×20.4 7.6 ×20.4 9.3 ×23.3
33 −6.7 ×15.3 7.6 ×20.4 7.6 ×20.4 9.3 ×23.3 9.3 ×23.3
47 6.7 ×15.3 6.7 ×15.3 7.6 ×20.4 7.6 ×20.4 9.3 ×23.3 10.3 ×32.0
68 6.7 ×15.3 7.6 ×20.4 7.6 ×20.4 9.3 ×23.3 10.3 ×32.0 10.3 ×32.0
100 −7.6 ×20.4 9.3 ×23.3 9.3 ×23.3 12.9 ×32.0 12.9 ×32.0
150 7.6 ×20.4 9.3 ×23.3 9.3 ×23.3 10.3 ×32.0 12.9 ×32.0 −
220 −9.3 ×23.3 10.3 ×32.0 12.9 ×32.0 −−
330 9.3 ×23.3 10.3 ×32.0 10.3 ×32.0 12.9 ×32.0 −−
470 −10.3 ×32.0 12.9 ×32.0 −−−
680 10.3 ×32.0 12.9 ×32.0 12.9 ×32.0 −−−
1000 12.9 ×32.0 12.9 ×32.0 −−−−
1500 12.9 ×32.0 −−−−−
1997 Nov 13 3
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
MECHANICAL DATA, AVAILABLE FORMS AND PACKAGING QUANTITIES
Table 1 Physical dimensions, mass and packaging quantities; see Fig.2
Note
1. Add 10% for SAL-AG epoxy-filled versions.
CASE Fmax
(mm) ∅d
(mm)
MASS
(g)
(note 1)
PACKAGING QUANTITIES
MAXIMUM SIZE
∅D×L
(mm) CODE FORM
BA FORM
BR
6.7 ×15.3 1 20.0 0.6 ≈1.05 100 800
7.6 ×20.4 2A 22.5 0.6 ≈1.55 100 800
9.3 ×23.3 4 25.0 0.6 ≈2.6 100 500
10.3 ×32.0 5 35.0 0.8 ≈4.2 100 500
12.9 ×32.0 6 35.0 0.8 ≈7 100 400
Fig.2 Forms: BA and BR.
Dimensions in mm.
BA: taped in box, (ammopack).
BR: taped on reel.
For dimensions see Table 1.
Tape dimensions are specified in this handbook, section
“Packaging”
.
handbook, full pagewidth
MBC589
Lmax
73
O D
O d
F
1997 Nov 13 4
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
ELECTRICAL DATA
Unless otherwise specified, all electrical values in Tables 2, 4 and 6 apply at Tamb =20to25°C, P = 86 to 106 kPa,
RH = 45 to 75%.
Table 2 Electrical data for 123 series; preferred types in bold
SYMBOL DESCRIPTION
CRrated capacitance at 100 Hz
IRmax. RMS ripple current, no necessary DC voltage applied
IL5 max. leakage current after 5 minutes at UR
Tan δmax. dissipation factor at 100 Hz
ESR max. equivalent series resistance at 100 Hz
Z max. impedance at 100 kHz
UR
(V)
CR
100 Hz
(µF)
MAXIMUM
CASE SIZE
∅D×L
(mm)
IR
100 Hz
125 °C
(mA)
IR
10 kHz
85 °C
(mA)
IR
100 kHz
40 °C
(mA)
IL5
5 min
(µA)
Tan δ
100 Hz
ESR
100 Hz
(Ω)
Z
100 kHz
(Ω)
6.3 47 6.7 ×15.3 58 440 640 15 0.18 7.6 1.2
68 6.7 ×15.3 83 520 760 21 0.18 5.3 1.2
150 7.6 ×20.4 160 870 1270 47 0.18 2.4 1.0
330 9.3 ×23.3 330 1470 2140 104 0.18 1.1 0.4
680 10.3 ×32.0 680 2340 3410 214 0.18 0.55 0.3
1000 12.9 ×32.0 940 3180 4640 315 0.18 0.36 0.2
1500 12.9 ×32.0 1220 4140 6020 473 0.18 0.24 0.2
10 33 6.7 ×15.3 63 360 530 17 0.18 11 1.2
47 6.7 ×15.3 83 440 640 24 0.18 7.6 1.2
68 7.6 ×20.4 110 590 850 34 0.18 5.3 1.0
100 7.6 ×20.4 160 710 1040 50 0.18 3.6 1.0
150 9.3 ×23.3 240 990 1450 75 0.18 2.4 0.4
220 9.3 ×23.3 350 1180 1720 110 0.18 1.7 0.4
330 10.3 ×32.0 490 1650 2410 165 0.18 1.1 0.3
470 10.3 ×32.0 570 1940 2830 235 0.18 0.8 0.3
680 12.9 ×32.0 760 2580 3750 340 0.18 0.55 0.2
1000 12.9 ×32.0 1000 3380 4920 500 0.18 0.36 0.2
1997 Nov 13 5
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
ORDERING INFORMATION
Ordering example
Electrolytic capacitors SAL A
10 µF/16 V; ±20%
Maximum case size: 6.7 ×15.3 mm; Form BR
Catalogue number: 2222 123 25109
Table 3 Ordering information for 123 series; preferred types in bold
UR
(V)
CR
100 Hz
(µF)
MAXIMUM
CASE SIZE
∅D×L
(mm)
CATALOGUE NUMBER 2222 ... .....
SAL-A
FORM BA
tol ±20%
SAL-A
FORM BR
tol ±20%
SAL-AG
FORM BA
tol. ±10%
level S
SAL-AG
FORM BA
tol. ±20%
6.3 47 6.7 ×15.3 123 13479 123 23479 123 83479 123 63479
68 6.7 ×15.3 123 13689 123 23689 123 83689 123 63689
150 7.6 ×20.4 123 13151 123 23151 123 83151 123 63151
330 9.3 ×23.3 123 13331 123 23331 123 83331 123 63331
680 10.3 ×32.0 123 13681 123 23681 123 83681 123 63681
1000 12.9 ×32.0 123 13102 123 23102 123 83102 123 63102
1500 12.9 ×32.0 123 13152 123 23152 123 83152 123 63152
10 33 6.7 ×15.3 123 14339 123 24339 123 84339 123 64339
47 6.7 ×15.3 123 14479 123 24479 123 84479 123 64479
68 7.6 ×20.4 123 14689 123 24689 123 84689 123 64689
100 7.6 ×20.4 123 14101 123 24101 123 84101 123 64101
150 9.3 ×23.3 123 14151 123 24151 123 84151 123 64151
220 9.3 ×23.3 123 14221 123 24221 123 84221 123 64221
330 10.3 ×32.0 123 14331 123 24331 123 84331 123 64331
470 10.3 ×32.0 123 14471 123 24471 123 84471 123 64471
680 12.9 ×32.0 123 14681 123 24681 123 84681 123 64681
1000 12.9 ×32.0 123 14102 123 24102 123 84102 123 64102
1997 Nov 13 6
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
ELECTRICAL DATA (continued)
Table 4 Electrical data for 123 series continued; preferred types in bold
UR
(V)
CR
100 Hz
(µF)
MAXIMUM
CASE SIZE
∅D×L
(mm)
IR
100 Hz
125 °C
(mA)
IR
10 kHz
85 °C
(mA)
IR
100 kHz
40 °C
(mA)
IL5
5 min
(µA)
Tan δ
100 Hz
ESR
100 Hz
(Ω)
Z
100 kHz
(Ω)
16 10 6.7 ×15.3 31 230 330 16 0.14 28 2.5
15 6.7 ×15.3 47 280 400 24 0.14 19 2.5
22 6.7 ×15.3 63 340 490 35 0.14 13 2.5
33 7.6 ×20.4 89 470 680 55 0.14 8.4 2.0
47 7.6 ×20.4 120 560 810 75 0.14 5.9 2.0
68 7.6 ×20.4 180 670 970 110 0.14 4.1 2.0
100 9.3 ×23.3 260 920 1340 160 0.14 2.8 0.8
150 9.3 ×23.3 310 1060 1550 240 0.16 2.1 0.8
220 10.3 ×32.0 420 1420 2060 350 0.16 1.5 0.6
330 10.3 ×32.0 510 1740 2530 500 0.16 1.0 0.6
470 12.9 ×32.0 680 2280 3330 750 0.16 0.7 0.4
680 12.9 ×32.0 850 2870 4170 870 0.16 0.5 0.4
25 10 6.7 ×15.3 43 230 330 25 0.14 28 5
15 6.7 ×15.3 60 280 400 35 0.14 19 5.0
22 7.6 ×20.4 88 370 550 55 0.14 13 2.5
33 7.6 ×20.4 130 470 680 85 0.14 8.4 2.5
47 7.6 ×20.4 160 560 810 100 0.14 5.9 2.5
68 9.3 ×23.3 230 760 1110 170 0.14 4.1 1.0
100 9.3 ×23.3 250 860 1250 250 0.16 3.2 1.0
150 10.3 ×32.0 350 1200 1740 400 0.16 2.1 0.8
220 12.9 ×32.0 460 1560 2270 550 0.16 1.5 0.6
330 12.9 ×32.0 600 2030 2950 800 0.16 1.0 0.6
35 1.0 6.7 ×15.3 4 55 80 5 0.12 240 16.5
1.5 6.7 ×15.3 7 68 98 5 0.12 160 11.0
2.2 6.7 ×15.3 10 82 120 5 0.12 109 7.5
3.3 6.7 ×15.3 14 100 150 7 0.12 73 7.5
4.7 6.7 ×15.3 20 120 170 10 0.12 51 7.5
6.8 6.7 ×15.3 27 140 210 15 0.12 35 7.5
10 7.6 ×20.4 37 200 280 20 0.12 24 2.5
15 7.6 ×20.4 53 240 350 30 0.12 16 2.5
22 7.6 ×20.4 78 290 420 45 0.12 11 2.5
33 9.3 ×23.3 120 410 590 65 0.12 7.2 1.0
47 9.3 ×23.3 140 480 700 95 0.12 5.1 1.0
68 10.3 ×32.0 170 570 820 135 0.16 4.7 0.8
100 12.9 ×32.0 220 760 1100 200 0.16 3.2 0.6
150 12.9 ×32.0 290 990 1440 300 0.16 2.1 0.6
1997 Nov 13 7
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
ORDERING INFORMATION (continued)
Table 5 Ordering information for 123 series continued; preferred types in bold
UR
(V)
CR
100 Hz
(µF)
MAXIMUM
CASE SIZE
∅D×L
(mm)
CATALOGUE NUMBER 2222 ... .....
SAL-A
FORM BA
tol ±20%
SAL-A
FORM BR
tol ±20%
SAL-AG
FORM BA
tol. ±10%
level S
SAL-AG
FORM BA
tol. ±20%
16 10 6.7 ×15.3 123 15109 123 25109 123 85109 123 65109
15 6.7 ×15.3 123 15159 123 25159 123 85159 123 65159
22 6.7 ×15.3 123 15229 123 25229 123 85229 123 65229
33 7.6 ×20.4 123 15339 123 25339 123 85339 123 65339
47 7.6 ×20.4 123 15479 123 25479 123 85479 123 65479
68 7.6 ×20.4 123 15689 123 25689 123 85689 123 65689
100 9.3 ×23.3 123 15101 123 25101 123 85101 123 65101
150 9.3 ×23.3 123 15151 123 25151 123 85151 123 65151
220 10.3 ×32.0 123 15221 123 25221 123 85221 123 65221
330 10.3 ×32.0 123 15331 123 25331 123 85331 123 65331
470 12.9 ×32.0 123 15471 123 25471 123 85471 123 65471
680 12.9 ×32.0 123 15681 123 25681 123 85681 123 65681
25 10 6.7 ×15.3 123 16109 123 26109 123 86109 123 66109
15 6.7 ×15.3 123 16159 123 26159 123 86159 123 66159
22 7.6 ×20.4 123 16229 123 26229 123 86229 123 66229
33 7.6 ×20.4 123 16339 123 26339 123 86339 123 66339
47 7.6 ×20.4 123 16479 123 26479 123 86479 123 66479
68 9.3 ×23.3 123 16689 123 26689 123 86689 123 66689
100 9.3 ×23.3 123 16101 123 26101 123 86101 123 66101
150 10.3 ×32.0 123 16151 123 26151 123 86151 123 66151
220 12.9 ×32.0 123 16221 123 26221 123 86221 123 66221
330 12.9 ×32.0 123 16331 123 26331 123 86331 123 66331
35 1.0 6.7 ×15.3 123 10108 123 20108 123 80108 123 60108
1.5 6.7 ×15.3 123 10158 123 20158 123 80158 123 60158
2.2 6.7 ×15.3 123 10228 123 20228 123 80228 123 60228
3.3 6.7 ×15.3 123 10338 123 20338 123 80338 123 60338
4.7 6.7 ×15.3 123 10478 123 20478 123 80478 123 60478
6.8 6.7 ×15.3 123 10688 123 20688 123 80688 123 60688
10 7.6 ×20.4 123 10109 123 20109 123 80109 123 60109
15 7.6 ×20.4 123 10159 123 20159 123 80159 123 60159
22 7.6 ×20.4 123 10229 123 20229 123 80229 123 60229
33 9.3 ×23.3 123 10339 123 20339 123 80339 123 60339
47 9.3 ×23.3 123 10479 123 20479 123 80479 123 60479
68 10.3 ×32.0 123 10689 123 20689 123 80689 123 60689
100 12.9 ×32.0 123 10101 123 20101 123 80101 123 60101
150 12.9 ×32.0 123 10151 123 20151 123 80151 123 60151
1997 Nov 13 8
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
ELECTRICAL DATA (continued)
Table 6 Electrical data for 123 series continued; preferred types in bold
ORDERING INFORMATION (continued)
Table 7 Ordering information for 123 series continued; preferred types in bold
UR
(V)
CR
100 Hz
(µF)
MAXIMUM
CASE SIZE
∅D×L
(mm)
IR
100 Hz
125 °C
(mA)
IR
10 kHz
85 °C
(mA)
IR
100 kHz
40 °C
(mA)
IL5
5 min
(µA)
Tan δ
100 Hz
ESR
100 Hz
(Ω)
Z
100 kHz
(Ω)
40 2.2 6.7 ×15.3 11 82 120 9 0.12 109 7.5
3.3 6.7 ×15.3 16 100 150 13 0.12 73 7.5
4.7 6.7 ×15.3 22 120 170 19 0.12 51 7.5
6.8 6.7 ×15.3 28 140 210 27 0.12 35 7.5
10 7.6 ×20.4 41 200 280 40 0.12 24 2.5
15 7.6 ×20.4 61 240 350 60 0.12 16 2.5
22 9.3 ×23.3 89 330 480 90 0.12 11 1.5
33 9.3 ×23.3 120 410 590 130 0.12 7.2 1.0
47 10.3 ×32.0 160 540 790 190 0.12 5.1 1.0
68 10.3 ×32.0 170 570 820 270 0.16 4.7 0.8
100 12.9 ×32.0 220 760 1100 400 0.16 3.2 0.6
UR
(V)
CR
100 Hz
(µF)
MAXIMUM
CASE SIZE
∅D×L
(mm)
CATALOGUE NUMBER 2222 ... .....
SAL-A
FORM BA
tol ±20%
SAL-A
FORM BR
tol ±20%
SAL-AG
FORM BA
tol. ±10%
level S
SAL-AG
FORM BA
tol. ±20%
40 2.2 6.7 ×15.3 123 17228 123 27228 123 87228 123 67228
3.3 6.7 ×15.3 123 17338 123 27338 123 87338 123 67338
4.7 6.7 ×15.3 123 17478 123 27478 123 87478 123 67478
6.8 6.7 ×15.3 123 17688 123 27688 123 87688 123 67688
10 7.6 ×20.4 123 17109 123 27109 123 87109 123 67109
15 7.6 ×20.4 123 17159 123 27159 123 87159 123 67159
22 9.3 ×23.3 123 17229 123 27229 123 87229 123 67229
33 9.3 ×23.3 123 17339 123 27339 123 87339 123 67339
47 10.3 ×32.0 123 17479 123 27479 123 87479 123 67479
68 10.3 ×32.0 123 17689 123 27689 123 87689 123 67689
100 12.9 ×32.0 123 17101 123 27101 123 87101 123 67101
1997 Nov 13 9
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
ELECTRICAL DATA (continued)
Additional electrical data
PARAMETER CONDITIONS VALUE
Surge voltage for short periods Us≤1.15 ×UR
Reverse voltage Urev <0.3 ×UR
Maximum peak AC voltage,
reverse voltage applied ≤2V
Maximum peak AC voltage,
without reverse voltage applied Tamb ≤85 °C
at f ≤0.1 Hz 0.30 ×UR
at 0.1 Hz <f≤1 Hz 0.45 ×UR
at 1 Hz <f≤10 Hz 0.60 ×UR
at 10 Hz <f≤50 Hz 0.65 ×UR
at f >50 Hz 0.80 ×UR
85 °C<Tamb ≤125 °C
at f ≤0.1 Hz 0.15 ×UR
at 0.1 Hz <f≤1 Hz 0.22 ×UR
at 1 Hz <f≤10 Hz 0.30 ×UR
at 10 Hz <f≤50 Hz 0.32 ×UR
at f >50 Hz 0.40 ×UR
Current
Maximum leakage current after 5 minutes at UR and Tamb =25°CI
L5 ≤0.05CR×UR or 2 µA whichever is
greater, see Tables 2, 4 and 6
Typical leakage current after 15 s at UR and Tamb =25°C
U
R= 6.3 to 16 V approx. 0.2 ×value stated in
Tables 2, 4 and 6
UR= 25 to 40 V approx. 0.1 ×value stated in
Tables 2, 4 and 6
1997 Nov 13 10
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Voltage
Ripple current (IR)
Applying the maximum RMS ripple current given in Tables 2, 4 and 6 will cause a device temperature of 138 °C. The
100 kHz values in Tables 2, 4 and 6 for other temperatures are to be calculated with the following IR multipliers:
Tamb 25 °C40°C65°C85°C 105 °C 125 °C
IR multiplier 1.1 1.0 0.88 0.75 0.59 0.37
Fig.3 Maximum permissible voltage up to 175 °C.
Curve 1: 6.3 to 25 V.
Curve 2: 35 and 40 V.
handbook, 4 columns
U
UR
(%)
50
T ( C)
050
85 100 125 150 175
0
33
50
66
100
MRA486
amb o
2
1
1997 Nov 13 11
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Leakage current
Fig.4 Typical multiplier of leakage current as a function of ambient temperature.
I01 = leakage current during continuous operation at UR and Tamb =25°C.
handbook, 4 columns
15050 0 50
MGB024
10
1
100 Tamb ( C)
o
I
01
I
10 2
10 1
Fig.5 Typical multiplier of leakage current as a function of U/UR.
I02 = leakage current at UR at a discrete constant temperature.
handbook, 4 columns
0.80.4 0 0.4
MGB025
10
1
I
02
I
10 1
U
R
U
reverse voltage
1997 Nov 13 12
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Maximum power dissipation
Equivalent series inductance (ESL), f = 10 MHz
MAXIMUM CASE SIZE
∅D×L
(mm)
Pmax =P
125
(W)
6.7 ×15.3 0.13
7.6 ×20.4 0.16
9.3 ×23.3 0.21
10.3 ×32.0 0.26
12.9 ×32.0 0.32
MAXIMUM CASE SIZE
∅D×L
(mm)
PITCH
(mm) MAX. ESL
(nH) TYP. ESL
(nH)
6.7 ×15.3 20.3 30 15 to 23
7.6 ×20.4 25.4 30 16 to 24
9.3 ×23.3 27.9 35 20 to 27
10.3 ×32.0 35.6 40 26 to 33
12.9 ×32.0 35.6 55 32 to 49
1997 Nov 13 13
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Dissipation factor (tan δ)
Capacitance (C)
Fig.6 Typical multiplier of dissipation factor as a function of ambient temperature.
Typical tan δ at 100 Hz and Tamb =25°C: 0.6 ×value stated in Tables 2, 4 and 6.
handbook, 4 columns
80 40 40
2.4
MGB026
0Tamb ( C)
o
80 120 160 200
0
tan δ
tan δ
2.0
1.6
1.2
0.8
0.4
0
standard deviation σ
σ0.25
0
Fig.7 Typical multiplier of capacitance as a function of ambient temperature.
C0= capacitance at 25 °C and 100 Hz.
handbook, 4 columns
80 40 40
1.1
1.0
0.8
0.9
MGB027
0Tamb ( C)
o
0
80 120 160 200
standard deviation σ
σ
0.05
0
C
C
1997 Nov 13 14
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Equivalent series resistance (ESR)
Typical ESR: see Figs 8 to 17; the standard deviation is 20% of each value.
Fig.8 Typical ESR as a function of ambient temperature.
handbook, 4 columns
MGB028
08040 120 160 200
Tamb ( C)
o
80
10
1
ESR
(Ω)
40
10 2
10 1
1
2
3
4
5
Curve 1: 10 µF, 20 and 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, 4 and 6.3 V.
Case ∅D×L = 6.7 ×15.3 mm.
ESR at 100 Hz.
Fig.9 Typical ESR as a function of ambient temperature.
Curve 1: 10 µF, 35 and 40 V.
Curve 2: 33 µF, 25 V.
Curve 3: 47 µF, 20 and 25 V.
Curve 4: 68 µF, 10 V; 150 µF, 6.3 V.
Curve 5: 100 µF, 10 V.
Case ∅D×L = 7.6 ×20.4 mm.
ESR at 100 Hz.
handbook, 4 columns
MGB029
08040 120 160 200
Tamb ( C)
o
80
10
1
40
ESR
(Ω)
10 2
10 1
1
2
3
4
5
1997 Nov 13 15
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Fig.10 Typical ESR as a function of ambient temperature.
Curve 1: 33 µF, 35 and 40 V.
Curve 2: 220 µF, 10 V; 330 µF, 6.3 V.
Curve 3: 470 µF, 4 V.
Case ∅D×L = 9.3 ×23.3 mm.
ESR at 100 Hz.
handbook, 4 columns
MGB030
08040 120 160 200
Tamb ( C)
o
80
10
1
ESR
(Ω)
40
102
10 1
1
2
3
Fig.11 Typical ESR as a function of ambient temperature.
Curve 1: 68 µF, 35 and 40 V.
Curve 2: 150 µF, 20 and 25 V.
Curve 3: 330 µF, 10 V.
Curve 4: 470 µF, 10 V.
Case ∅D×L = 10.3 ×32.0 mm.
ESR at 100 Hz.
handbook, 4 columns
MGB031
08040 120 160 200
Tamb ( C)
o
80
10
1
ESR
(Ω)
40
10 2
10 1
1
2
3
4
1997 Nov 13 16
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Curve 1: 100 µF, 35 and 40 V.
Curve 2: 150 µF, 35 V.
Curve 3: 220 µF, 25 V.
Curve 5: 680 µF, 10 V; 1000 µF, 6.3 V.
Curve 4: 470 µF, 16 V.
Case ∅D×L = 12.9 ×32.0 mm.
ESR at 100 Hz.
Fig.12 Typical ESR as a function of ambient temperature.
handbook, 4 columns
MGB032
08040 120 160 200
Tamb ( C)
o
80
10
1
ESR
(Ω)
40
102
10 1
1
2
3
4
5
handbook, 4 columns
MGB033
106
105
104
103
102
10 f (Hz)
103
102
10
1
10 1
ESR
(Ω)
1
1
2
3
4
5
Fig.13 Typical ESR as a function of frequency.
Curve 1: 10 µF, 20 and 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, 4 and 6.3 V.
Case ∅D×L = 6.7 ×15.3 mm.
Tamb =25°C.
1997 Nov 13 17
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Fig.14 Typical ESR as a function of frequency.
Curve 1: 10 µF, 35 and 40 V.
Curve 2: 33 µF, 25 V.
Curve 3: 47 µF, 20 and 25 V.
Curve 4: 68 µF, 10 V; 150 µF, 6.3 V.
Curve 5: 100 µF, 10 V.
Case ∅D×L = 6.7 ×20.4 mm.
Tamb =25°C.
handbook, 4 columns
MGB034
106
105
104
103
102
10 f (Hz)
103
102
10
1
1
ESR
(Ω)
10 1
1
2
3
4
5
handbook, 4 columns
MGB035
106
105
104
103
102
10 f (Hz)
1
102
10
1
ESR
(Ω)
10 1
10 2
1
2
Curve 1: 33 µF, 35 and 40 V.
Curve 2: 220 µF, 10 V; 330 µF, 6.3 V; 470 µF, 4 V.
Case ∅D×L = 9.3 ×23.3 mm.
Tamb =25°C.
Fig.15 Typical ESR as a function of frequency.
1997 Nov 13 18
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Fig.16 Typical ESR as a function of frequency.
Curve 1: 68 µF, 35 and 40 V.
Curve 2: 150 µF, 20 and 25 V.
Curve 3: 330 µF, 10 V.
Curve 4: 470 µF, 10 V.
Case ∅D×L = 10.3 ×32.0 mm.
Tamb =25°C.
handbook, 4 columns
MGB036
106
105
104
103
102
10 f (Hz)
1
102
10
1
ESR
(Ω)
10 1
10 2
1
2
3
4
Fig.17 Typical ESR as a function of frequency.
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.
Case ∅D×L = 12.9 ×32.0 mm.
Tamb =25°C.
handbook, 4 columns
MGB037
106
105
104
103
102
10 f (Hz)
1
102
10
1
ESR
(Ω)
10 1
10 2
1
2
3
4
5
1997 Nov 13 19
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Impedance (Z)
Typical impedance at 100 kHz and Tamb =25°C: 0.5 ×value stated in Tables 2, 4 and 6.
Fig.18 Typical multiplier of impedance as a function of frequency at different ambient temperatures.
Curve 1: case ∅D×L = 6.7 ×15.3 and 7.6 ×20.4 mm;16to40V.
Curve 2: case ∅D×L = 6.7 ×15.3 and 7.6 ×20.4 mm; 4 to 10 V.
Curve 3: case ∅D×L = 9.3 ×32.0, 10.3 ×32.0 and 12.9 ×32.0 mm.
Z0= initial impedance value at any frequency and Tamb =25°C.
handbook, full pagewidth
MGB038
2.0
0
0.5
10 10210 3104105106107
1.5
1.0
2.5
3.5
3.0
standard deviation σ (%)
1147
10 10 3
f (Hz)
Z
0
Z1
2
3
1
2
3
1
2
3
+175 C
o
+85 C
o
–55 C
o
+25 C
o
–25 C
o
1
2
3
1997 Nov 13 20
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Fig.19 Typical impedance as a function of frequency.
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, 4 and 6.3 V.
Curve 7: 100 µF, 4 V.
Case ∅D×L = 6.7 ×15.3 mm;U
R= 4 to 16 V.
Tamb =25°C.
handbook, 4 columns
106
MGB039
105
104
103
102
10 107
f (Hz)
103
102
10
1
Z
( )Ω
10 1
1
2
3
4
5
6
7
Fig.20 Typical impedance as a function of frequency.
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, 20 and 25 V.
Curve 6: 15 µF, 20 and 25 V.
Case ∅D×L = 6.7 ×15.3 mm;U
R=20to40V.
T
amb =25°C.
handbook, 4 columns
106
MGB040
105
104
103
102
10 107
f (Hz)
103
102
10
1
104
Z
( )Ω
1
2
3
4
5
6
1997 Nov 13 21
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Curve 1: 33 µF, 16 V.
Curve 2: 47 µF, 16 V.
Curve 3: 68 µF, 10 V.
Curve 4: 100 µF, 10 V.
Curve 5: 150 µF, 6.3 V.
Curve 6: 220 µF, 4 V.
Case ∅D×L = 6.7 ×20.4 mm;U
R= 4 to 16 V.
Tamb =25°C.
Fig.21 Typical impedance as a function of frequency.
handbook, 4 columns
106
MGB041
105
104
103
102
10 107
f (Hz)
103
102
10
1
Z
( )Ω
10 1
1
2
3
4
5
6
Curve 1: 10 µF, 35 and 40 V.
Curve 2: 15 µF, 35 and 40 V.
Curve 3: 22 µF, 25 and 35 V.
Curve 4: 33 µF, 25 V.
Curve 5: 47 µF, 20 and 25 V.
Curve 6: 68 µF, 16 V.
Case ∅D×L = 6.7 ×20.4 mm;U
R=16to40V.
T
amb =25°C.
Fig.22 Typical impedance as a function of frequency.
handbook, 4 columns
106
MGB042
105
104
103
102
10 107
f (Hz)
103
102
10
1
Z
( )Ω
10 1
1
2
3
4
5
6
1997 Nov 13 22
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Fig.23 Typical impedance as a function of frequency.
Curve 1: 150 µF, 10 V.
Curve 2: 220 µF, 10 V.
Curve 3: 330 µF, 6.3 V.
Curve 4: 470 µF, 4 V.
Case ∅D×L = 9.3 ×23.3 mm;U
R= 4 to 10 V.
Tamb =25°C.
handbook, 4 columns
106
MGB043
105
104
103
102
10 107
f (Hz)
102
10
1
Z
( )Ω
10 1
10 2
1
2
3
4
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, 20 and 25 V.
Curve 6: 150 µF, 16 V.
Case ∅D×L = 9.3 ×23.3 mm;U
R=16to40V.
T
amb =25°C.
Fig.24 Typical impedance as a function of frequency.
handbook, 4 columns
106
MGB044
105
104
103
102
10 107
f (Hz)
103
102
10
1
Z
( )Ω
10 1
1
2
3
4
5
6
1997 Nov 13 23
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Fig.25 Typical impedance as a function of frequency.
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.
Curve 6: 1000 µF, 4 V.
Case ∅D×L = 10.3 ×32.0 mm;U
R= 4 to 16 V.
Tamb =25°C.
handbook, 4 columns
106
MGB045
105
104
103
102
10 107
f (Hz)
102
10
1
Z
( )Ω
10 1
10 2
1
2
3
4
5
6
Fig.26 Typical impedance as a function of frequency.
Curve 1: 47 µF, 40 V.
Curve 2: 68 µF, 35 and 40 V.
Curve 3: 150 µF, 20 and 25 V.
Curve 4: 220 µF, 20 V.
Case ∅D×L = 10.3 ×32.0 mm;U
R=20to40V.
T
amb =25°C.
handbook, 4 columns
106
MGB046
105
104
103
102
10 107
f (Hz)
103
102
10
1
Z
( )Ω
10 1
1
2
3
4
3, 4
1, 2
1997 Nov 13 24
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Fig.27 Typical impedance as a function of frequency.
Curve 1: 680 µF, 10 V.
Curve 2: 1000 µF, 6.3 V.
Curve 3: 1500 µF, 6.3 V.
Curve 4: 2200 µF, 4 V.
Case ∅D×L = 12.9 ×32.0 mm;U
R= 4 to 10 V.
Tamb =25°C.
handbook, 4 columns
106
MGB047
105
104
103
102
10 107
f (Hz)
102
10
1
Z
( )Ω
10 1
10 2
1
2
3
4
3, 4
1, 2
Fig.28 Typical impedance as a function of frequency.
Curve 1: 100 µF, 35 and 40 V.
Curve 2: 150 µF, 35 V.
Curve 3: 220 µF, 25 V.
Curve 4: 330 µF, 20 V.
Curve 5: 470 µF, 16 and 20 V.
Curve 6: 680 µF, 16 .V
Curve 7: 1000 µF, 10 V.
Case ∅D×L = 12.9 ×32.0 mm;U
R=10to40V.
T
amb =25°C.
handbook, 4 columns
106
MGB048
105
104
103
102
10 107
f (Hz)
102
10
1
Z
( )Ω
10 1
10 2
1
2
3
4
5
6
7
1997 Nov 13 25
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
SPECIFIC TESTS AND REQUIREMENTS
General tests and requirements are specified in this handbook, section
“Tests and Requirements”
.
Table 8 Test procedures and requirements
TEST PROCEDURE
(quick reference) REQUIREMENTS
NAME OF TEST REFERENCE
Endurance IEC 384-2/
CECC 30300
subclause 4.13
Tamb = 125 °C;
UR= 6.3 to 25 V with UR applied;
UR= 35 and 40 V with UC applied;
10000 hours
∆C/C: ±10%
tan δ≤1.2 ×spec. limit
Z≤1.2 ×spec. limit
IL5 ≤spec. limit
Useful life CECC 30302
subclause 1.8.1 Tamb = 125 °C; IR applied and
UR= 6.3 to 25 V with UR applied;
UR= 35 and 40 V with UC applied;
20000 hours
∆C/C: ±15%
tan δ≤1.5 ×spec. limit
Z≤1.5 ×spec. limit
IL5 ≤spec. limit
no short or open circuit, no
visible damage
total failure percentage: <1%
Shelf life
(storage at high
temperature)
IEC 384-4/
CECC 30300
subclause 4.17
Tamb = 125 °C; no voltage applied;
500 hours ∆C/C: ±10%
tan δ≤1.2 ×spec. limit
IL5 ≤1×spec. limit
Charge and
discharge IEC 384-4-2
subclause 9.21 106 cycles without series resistance;
0.5 s to UR;
0.5 s to ground
∆C/C: ±5%
no short or open circuit, no
visible damage
Shock IEC 68-2-27
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
no intermittent contacts
no breakdown
no open circuiting
no mechanical damage
∆C/C: ±5%
tan δ≤1.2 ×spec. limit
Z≤1.2 ×spec. limit
IL5 ≤1.5 ×spec. limit
1997 Nov 13 26
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
Severe rapid
change of
temperature
100 cycles of 30 minutes
at −40 °C and +125 °C∆C/C: ±10%
tan δ≤1.6 ×spec. limit
Z≤1.6 ×spec. limit
IL5 ≤1× spec.limit
Solvent resistance IEC 68-2-45,
test XA
IEC 653
immersion:
5±0.5 minutes with or without ultrasonic
at 55 ±5°C
Solvents: demineralized water and/or
calgonite solution (20 g/l)
visual appearance not affected
Passive
flammability IEC 695-2-2 capacitor mounted to a vertical
printed-circuit board, one flame on
capacitor body; Tamb =20to25°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
TEST PROCEDURE
(quick reference) REQUIREMENTS
NAME OF TEST REFERENCE
1997 Nov 13 27
Philips Components Product specification
Solid Al - electrolytic capacitors
Solid Al, Axial SAL-A 123
ADDITIONAL TESTS AND REQUIREMENTS FOR EPOXY-FILLED VERSIONS SAL-AG
2222 123 6.... Form BA ±20%
2222 123 8.... Form BA ±10%, level S
Table 9 Test procedures and requirements
TEST PROCEDURE REQUIREMENTS
Severe vibration tests in accordance with
“IEC 68-2-6”
and
“MIL STD-202”
, method 204, letter E, with the
following details and additions
Method of mounting: clamping both body and leads ∆C/C: ±10%
tan δ≤1.2 ×stated limit
Z≤1.4 ×stated limit
DC leakage current: ≤stated limit
no intermittent contacts
no indication of breakdown
no open circuiting
no evidence of mechanical
damage
severity 1 frequency range temperature
10 to 3000 Hz; 20-25 °C
severity 2 frequency range temperature
50 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/minute; 3 directions (mutually
perpendicular); 20 sweeps per direction (total
60 sweeps or 18 hours)
severity 2 1 octave/minute; 2 directions (longitudinal
and transversal);
3 sweeps per direction (total 6 sweeps or
1 hour)
Functioning:
severity 1 rated voltage applied
severity 2 no voltage applied
Typical capability >80 g at 10 to 3000 Hz (also at 125 °C)
Severe shock tests in accordance with
“IEC 68-2-27”
and
“MIL STD-202”
, method 213, letter F, with the
following details and additions:
Method of mounting clamping both body and leads ∆C/C: ±10%
tan δ≤1.2 ×stated limit
Z≤1.4 ×stated limit
DC leakage current: ≤stated limit
no intermittent contacts
no indication of breakdown
no open circuiting
no evidence of mechanical
damage
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 10000 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
