DATA SH EET
Product specification
Supersedes data of January 1998
File under BC Components, BC01
2000 Jan 18
BC COMPONENTS
051/053 PEC-PW
Aluminum electrolytic capacitors
Power Economic Printed Wiring
2000 Jan 18 2
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
FEATURES
•Polarized aluminum electrolytic
capacitors, non-solid electrolyte
•Large types with reduced
dimensions, cylindrical aluminum
case, insulated with a blue sleeve
•Provided with keyed polarity
•Pressure relief on the top of the
aluminium case
•Charge and discharge proof
•Long useful life:
12000 hours at 85 °C
•High ripple current capability
•High resistance to shock and
vibration.
APPLICATIONS
•General purpose, industrial and
audio/video systems
•Smoothing and filtering
•Standard and switched mode
power supplies
•Energy storage in pulse systems.
Fig.1 Component outlines.
handbook, 4 columns
CCB065
handbook, 4 columns
CCB036
051/053
PEC-PW
high
ripple
current
050/052
PED-PW 162/163
PLL-PW
long life
105 °C
QUICK REFERENCE DATA
DESCRIPTION VALUE
051 053
Case size (∅Dnom ×Lnom in mm) 25 ×30 to 40 ×100
Rated capacitance range (E6 series), CR680 to 150000 µF 68 to 2200 µF
Tolerance on CR±20%
Rated voltage range, UR10 to 100 V 200 to 400 V
Category temperature range −40 to +85 °C
Endurance test at 85 °C 5000 hours
Useful life at 85 °C 12000 hours
Useful life at 40 °C, 1.4 ×IR applied 200000 hours
Shelf life at 0 V, 85 °C 500 hours
Based on sectional specification IEC 60384-4/EN130300
Climatic category IEC 60068 40/085/56
2000 Jan 18 3
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
Selection chart for CR, UR and relevant nominal case sizes (∅D×L in mm)
Preferred types in bold
CR
(µF) UR (V)
10 16 25 40 63 100 200 385 400
68 −−−−−−−25 ×30 25 ×30
100 −−−−−−−25 ×40 25 ×40
150 −−−−−−25 ×30 30 ×40 30 ×40
220 −−−−−−25 ×40 35 ×40 35 ×40
330 −−−−−−30 ×40 35 ×50 35 ×50
−−−−−−−40 ×40 40 ×40
470 −−−−−−35 ×40 40 ×50 40 ×50
680 −−−−−25 ×30 35 ×50 40 ×70 40 ×70
−−−−−−40 ×40 −−
1000 −−−−−25 ×40 40 ×50 40 ×100 40 ×100
1500 −−−−−30 ×40 40 ×70 −−
2200 −−−−25 ×30 35 ×40 40 ×100 −−
3300 −−−25 ×30 25 ×40 35 ×50 −−−
−−−−−40 ×40 −−−
4700 −−25 ×30 25 ×40 30 ×40 40 ×50 −−−
6800 −25 ×30 25 ×40 30 ×40 35 ×40 40 ×70 −−−
10000 25 ×30 25 ×40 30 ×40 35 ×40 35 ×50 40 ×100 −−−
−−−−40 ×40 −−−−
15000 25 ×40 30 ×40 35 ×40 35 ×50 40 ×70 −−−−
−−−40 ×40 −−−−−
22000 30 ×40 35 ×40 35 ×50 40 ×50 40 ×100 −−−−
−−40 ×40 −−−−−−
33000 35 ×40 35 ×50 40 ×50 40 ×70 −−−−−
−40 ×40 −−−−−−−
47000 35 ×50 40 ×50 40 ×70 40 ×100 −−−−−
40 ×40 −−−−−−−−
68000 40 ×50 40 ×70 40 ×100 −−−−−−
100000 40 ×70 40 ×100 −−−−−−−
150000 40 ×100 −−−−−−−−
2000 Jan 18 4
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
MECHANICAL DATA AND PACKAGING QUANTITIES
Fig.2 Printed wiring pin version.
Dimensions in mm; for L see Table 1.
1 = positive terminal; 5 = negative terminal.
Case ∅D = 25 mm.
∅D + 1 max.
handbook, halfpage
CCA975
LL + 5 max.
5.1
±0.1
2
15
handbook, halfpage
MGB266
10 0.1
1.3
(3x)
12.5
0.1
2.5
1
2
5
Fig.3 Mountingholediagram viewed
from component side.
Dimensions in mm.
Case ∅D = 25 mm.
∅D + 1 max.
handbook, halfpage
CCA976
L
1 2
3
5
L + 5 max.
5.1
±0.1
Fig.4 Printed wiring pin version.
Dimensions in mm; for L see Table 1.
1 = positive terminal; 5 = negative terminal.
Case ∅D = 30 mm.Fig.5 Mountingholediagramviewed
from component side.
handbook, halfpage
MGB267
15 0.1
1.3
(4x)
7.5 0.1 17.5 0.1
2.5
1
2
3
5
Dimensions in mm.
Case ∅D = 30 mm.
2000 Jan 18 5
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
Fig.6 Printed wiring pin version.
Dimensions in mm; for L see Table 1.
1 = positive terminal; 5 = negative terminal.
Case ∅D = 35 mm.
∅D + 1 max.
handbook, halfpage
CCA977
L
1 2
3
5
L + 5 max.
5.1
±0.1
Fig.7 Mountingholediagram viewed
from component side.
handbook, halfpage
MGB268
15 0.1
1.3
(4x)
7.5 0.1 17.5 0.1
2.5
1
2
3
5
Dimensions in mm.
Case ∅D = 35 mm.
Table 1 Physical dimensions, mass and packaging information; see Figs 2, 4, 6 and 8
NOMINAL
CASE SIZE
∅D×L
(mm)
∅Dmax
(mm) Lmax
(mm) MASS
(g) PACKAGING QUANTITIES
(units per box)
CARDBOARD
BOX DIMENSIONS
l×w×h
(mm)
25 ×30 26 35 ≈24 100 290 ×280 ×50
25 ×40 26 45 ≈28 100 290 ×280 ×60
30 ×40 31 45 ≈38 100 340 ×330 ×60
35 ×40 36 45 ≈51 50 390 ×198 ×60
35 ×50 36 55 ≈66 50 390 ×198 ×70
40 ×40 41 45 ≈78 50 440 ×223 ×60
40 ×50 41 55 ≈82 50 440 ×223 ×70
40 ×70 41 75 ≈110 50 440 ×223 ×90
40 ×100 41 105 ≈176 50 440 ×223 ×120
2000 Jan 18 6
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
Dimensions in mm; for L see Table 1.
1 = positive terminal; 5 = negative terminal.
Case ∅D = 40 mm.
Fig.8 Printed wiring pin version.
handbook, halfpage
CCA978
L
145
3
2
∅D + 1 max.
L + 5 max.
5.1
±0.1
Dimensions in mm.
Case ∅D = 40 mm.
Fig.9 Mountingholediagramviewed
from component side.
handbook, halfpage
MGB269
20 0.1
1.3
(5x)
10 0.1 17.5 0.1
2.5
20 0.1
1
2
3
4
5
Mounting
When a number of capacitors are connected in a bank,
they must not be closer together than 15 mm, when no
derating of ripple current and/or temperature is applied.
Pin numbers 2, 3 and 4 (if present) must be free from
the electrical circuit.
MARKING
The capacitors are marked (where possible) with the
following information:
•Rated capacitance (in µF)
•Tolerance on rated capacitance (M for ±20%)
•Rated voltage (in V)
•Climatic category in accordance with
“IEC 60068”
•Date code (year and week) in accordance with
“IEC 60062”
•Code for factory of origin
•Name of manufacturer
•Polarity of the terminals and ‘−’ sign to indicate the
negativeterminal,visiblefromthetop and/or side of the
capacitor
•Code number
•Code for basic specification in accordance with
“IEC 60384-4-1”
and
“CECC 30301”
.
2000 Jan 18 7
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
ELECTRICAL DATA AND ORDERING INFORMATION
Unless otherwise specified, all electrical values in Tables 2 and 3 apply at
Tamb =20°C, P = 86 to 106 kPa, RH = 45 to 75%.
SYMBOL DESCRIPTION
CRrated capacitance at 100 Hz
IRrated RMS ripple current at 100 Hz, 85 °C or at 20 kHz, 70 °C
IL1 max. leakage current after 1 minute at UR
IL5 max. leakage current after 5 minutes at UR
ESR max. equivalent series resistance at 100 Hz
Z max. impedance at 10 kHz
Ordering example
Electrolytic capacitor 051 series
10000 µF/25 V; ±20%
Nominal case size: ∅30 ×40 mm
Catalogue number: 2222 051 56103.
Table 2 Electrical data and ordering information for 051 series; preferred types in bold
UR
(V)
CR
100 Hz
(µF)
NOMINAL
CASE SIZE
∅D×L
(mm)
IR
100 Hz
85 °C
(A)
IR
20 kHz
70 °C
(A)
IL1
1 min
(mA)
IL5
5 min
(mA)
ESR
100 Hz
(mΩ)
Z
10 kHz
(mΩ)
CATALOGUE
NUMBER
2222 ... .....
10 10000 25 ×30 3.1 5.9 0.60 0.20 51 40 051 54103
15000 25 ×40 4.1 7.8 0.90 0.30 37 30 051 54153
22000 30 ×40 5.0 9.5 1.32 0.44 30 25 051 54223
33000 35 ×40 5.5 10.4 1.98 0.66 28 24 051 54333
47000 35 ×50 6.8 12.9 2.82 0.94 23 20 051 54473
47000 40 ×40 5.8 10.4 2.82 0.94 29 22 051 44473
68000 40 ×50 7.1 13.5 4.08 1.36 24 20 051 54683
100000 40 ×70 9.2 17.4 6.00 2.00 19 16 051 54104
150000 40 ×100 12.0 22.7 9.00 3.00 16 14 051 54154
16 6800 25 ×30 3.1 5.9 0.65 0.22 53 42 051 55682
10000 25 ×40 4.0 7.6 0.96 0.32 39 34 051 55103
15000 30 ×40 5.0 9.5 1.44 0.48 31 27 051 55153
22000 35 ×40 5.5 10.4 2.12 0.71 29 26 051 55223
33000 35 ×50 6.7 12.7 3.17 1.06 23 21 051 55333
33000 40 ×40 5.7 10.8 3.17 1.06 30 24 051 45333
47000 40 ×50 7.0 13.3 4.52 1.51 24 20 051 55473
68000 40 ×70 9.2 17.4 6.53 2.18 19 16 051 55683
100000 40 ×100 12.0 22.7 9.60 3.20 16 14 051 55104
25 4700 25 ×30 2.9 5.5 0.71 0.24 60 42 051 56472
6800 25 ×40 3.9 7.4 1.02 0.34 42 34 051 56682
10000 30 ×40 4.8 9.1 1.50 0.50 34 27 051 56103
15000 35 ×40 5.3 10.0 2.25 0.75 30 26 051 56153
22000 35 ×50 6.5 12.3 3.30 1.10 24 21 051 56223
22000 40 ×40 5.7 10.8 3.30 1.10 31 24 051 46223
33000 40 ×50 7.0 13.3 4.95 1.65 25 20 051 56333
47000 40 ×70 9.2 17.4 7.05 2.35 19 16 051 56473
68000 40 ×100 12.0 22.7 10.20 3.40 16 14 051 56683
2000 Jan 18 8
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
40 3300 25 ×30 2.9 5.5 0.80 0.27 87 63 051 57332
4700 25 ×40 3.8 7.2 1.13 0.38 62 47 051 57472
6800 30 ×40 4.7 8.9 1.64 0.55 49 38 051 57682
10000 35 ×40 5.2 9.8 2.40 0.80 48 37 051 57103
15000 35 ×50 6.3 11.9 3.60 1.20 37 28 051 57153
15000 40 ×40 5.6 10.6 3.60 1.20 50 35 051 47153
22000 40 ×50 5.8 11.0 5.28 1.76 39 28 051 57223
33000 40 ×70 7.8 14.8 7.92 2.64 28 21 051 57333
47000 40 ×100 10.4 19.7 11.28 3.76 22 17 051 57473
63 2200 25 ×30 2.5 4.7 0.84 0.28 83 62 051 58222
3300 25 ×40 3.3 6.2 1.25 0.42 58 42 051 58332
4700 30 ×40 4.1 7.8 1.78 0.60 49 38 051 58472
6800 35 ×40 4.5 8.5 2.57 0.86 48 37 051 58682
10000 35 ×50 5.4 10.2 3.78 1.26 37 28 051 58103
10000 40 ×40 4.6 8.7 3.78 1.26 52 37 051 48103
15000 40 ×70 7.5 14.2 5.67 1.89 29 24 051 58153
22000 40 ×100 10.0 19.0 8.32 2.77 22 19 051 58223
100 680 25 ×30 1.74 3.30 0.41 0.14 190 130 051 59681
1000 25 ×40 2.34 4.44 0.60 0.20 130 90 051 59102
1500 30 ×40 2.95 5.59 0.90 0.30 95 67 051 59152
2200 35 ×40 3.69 7.00 1.32 0.44 71 53 051 59222
3300 35 ×50 4.37 8.29 1.98 0.66 55 41 051 59332
3300 40 ×40 4.16 7.89 1.98 0.66 64 48 051 49332
4700 40 ×50 5.21 9.88 2.82 0.94 49 38 051 59472
6800 40 ×70 6.97 13.22 4.08 1.36 35 28 051 59682
10000 40 ×100 9.50 18.00 6.00 2.00 26 21 051 59103
UR
(V)
CR
100 Hz
(µF)
NOMINAL
CASE SIZE
∅D×L
(mm)
IR
100 Hz
85 °C
(A)
IR
20 kHz
70 °C
(A)
IL1
1 min
(mA)
IL5
5 min
(mA)
ESR
100 Hz
(mΩ)
Z
10 kHz
(mΩ)
CATALOGUE
NUMBER
2222 ... .....
2000 Jan 18 9
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
Table 3 Electrical data and ordering information for 053 series; preferred types in bold
UR
(V)
CR
100 Hz
(µF)
NOMINAL
CASE SIZE
∅D×L
(mm)
IR
100 Hz
85 °C
(A)
IR
20 kHz
70 °C
(A)
IL1
1 min
(mA)
IL5
5 min
(mA)
ESR
100 Hz
(mΩ)
Z
10 kHz
(mΩ)
CATALOGUE
NUMBER
2222 ... .....
200 150 25 ×30 0.70 1.33 0.18 0.06 1000 770 053 52151
220 25 ×40 0.94 1.78 0.26 0.09 680 525 053 52221
330 30 ×40 1.27 2.41 0.40 0.14 460 360 053 52331
470 35 ×40 1.66 3.15 0.57 0.19 320 250 053 52471
680 35 ×50 2.19 4.15 0.82 0.28 220 170 053 52681
680 40 ×40 2.17 4.11 0.82 0.28 220 170 053 42681
1000 40 ×50 2.86 5.42 1.20 0.40 150 115 053 52102
1500 40 ×70 3.81 7.22 1.80 0.60 110 85 053 52152
2200 40 ×100 5.20 9.86 2.64 0.88 80 60 053 52222
385 68 25 ×30 0.47 0.89 0.16 0.06 2200 1480 053 58689
100 25 ×40 0.64 1.21 0.23 0.08 1500 1020 053 58101
150 30 ×40 0.90 1.71 0.35 0.12 1000 700 053 58151
220 35 ×40 1.15 2.18 0.51 0.17 680 480 053 58221
330 35 ×50 1.53 2.90 0.77 0.26 450 340 053 58331
330 40 ×40 1.52 2.88 0.77 0.26 450 340 053 48331
470 40 ×50 1.96 3.72 1.09 0.36 320 260 053 58471
680 40 ×70 2.70 5.12 1.58 0.53 220 190 053 58681
1000 40 ×100 3.70 7.02 2.31 0.78 180 140 053 58102
400 68 25 ×30 0.54 1.02 0.16 0.06 2100 1000 053 56689
100 25 ×40 0.73 1.38 0.24 0.08 1400 780 053 56101
150 30 ×40 0.98 1.86 0.36 0.12 950 520 053 56151
220 35 ×40 1.28 2.43 0.52 0.17 650 400 053 56221
330 35 ×50 1.67 3.17 0.79 0.26 480 280 053 56331
330 40 ×40 1.67 3.17 0.79 0.26 480 280 053 46331
470 40 ×50 2.12 4.02 1.12 0.37 340 220 053 56471
680 40 ×70 2.90 5.50 1.63 0.54 235 155 053 56681
1000 40 ×100 4.05 7.68 2.40 0.80 160 110 053 56102
2000 Jan 18 10
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
Additional electrical data
Capacitance (C)
PARAMETER CONDITIONS VALUE
Voltage
Surge voltage ≤250 V versions Us= 1.15 ×UR
≥385 V versions Us= 1.1 ×UR
Reverse voltage Urev ≤1V
Current
Leakage current after 1 minute at URIL1 ≤0.006CR×UR+4µA
after 5 minutes at URIL5 ≤0.002CR×UR+4µA
Inductance
Equivalent series inductance (ESL) case ∅D = 25 mm max. 25 nH
case ∅D = 30 and 35 mm max. 30 nH
case ∅D = 40 mm max. 35 nH
Fig.10 Typical multiplier of capacitance as a function of ambient temperature.
Curve 1: UR= 100 V and 200 V.
Curve 2: UR=10V,16V,25V,40Vand63V.
Curve 3: UR= 385 V.
C0= capacitance at 20 °C and 100 Hz.
handbook, 4 columns
020
MGB271
40 20 40 60 80
0.8
0.9
1.0
C
0
100
1.1
Tamb ( C)
o
2
C
1
1, 3
2, 3
2000 Jan 18 11
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
Fig.11 Typical multiplier of capacitance as a function of frequency.
Curve 1: UR= 100 V and 200 V.
Curve 2: UR= 40 V and 63 V.
Curve 3: UR= 25 V and 385 V.
Curve 4: UR= 10 V and 16 V.
C0= capacitance at 20 °C and 100 Hz.
handbook, 4 columns
0.8 104
MGB270
103
102
10 f (Hz)
0.9
1.0
1.1
4
C
0
C
1
1
2
3
4
Equivalent series resistance (ESR)
Fig.12 Typical multiplier of typical ESR as a function of frequency.
Curve 1: UR=10V,16Vand25V.
Curve 2: UR=40V,63Vand385V.
Curve 3: UR= 100 V and 200 V.
ESR0= typical at 20 °C and 100 Hz.
handbook, 4 columns
105
MGB272
104
103
102
10 f (Hz)
0.6
0.8
1.0
1.2
1.4
ESR0
ESR
1
3
1
2
3
2
2000 Jan 18 12
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
Curve 1: UR= 385 V.
Curve 2: UR= 100 V and 200 V.
Curve 3: UR=10Vto63V.
ESR0= typical at 20 °C and 100 Hz.
Case ∅D×L=25×30, 25 ×40, 30 ×40 and 35 ×40 mm.
handbook, 4 columns
MGB273
0 50 100
1
10
10
50 Tamb ( C)
o
ESR0
ESR
2
10 1
1
2
3
1
2
3
Fig.13 Typical multiplier of ESR as a function of ambient temperature.
Fig.14 Typical multiplier of ESR as a function of ambient temperature.
Curve 1: UR= 385 V.
Curve 2: UR= 200 V.
Curve 3: UR= 100 V.
Curve 4: UR=10Vto63V.
ESR0= typical at 20 °C and 100 Hz.
Case ∅D×L=35×50, 40 ×40, 40 ×50, 40 ×70 and 40 ×100 mm.
handbook, 4 columns
MGB274
0 50 100
1
10
50 Tamb ( C)
o
ESR0
ESR
4
10 1
10 2
1
2
3
4
1
2,3
2000 Jan 18 13
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
Impedance (Z)
Curve 1: UR= 385 V.
Curve 2: UR= 200 V.
Curve 3: UR= 100 V.
Curve 4: UR=10Vto63V.
Z0= typical impedance at 20 °C and 10 kHz.
Case ∅D×L=25×30, 25 ×40, 30 ×40 and 35 ×40 mm.
handbook, 4 columns
MGB275
0 50 100
1
10
50 Tamb ( C)
o
2
10 1
Z0
Z
10 2
4
1
2,3
1
3
4
Fig.15 Typical multiplier of impedance as a function of ambient temperature.
Curve 1: UR= 385 V.
Curve 2: UR= 200 V.
Curve 3: UR= 100 V.
Curve 4: UR=10Vto63V.
Z0= typical impedance at 20 °C and 10 kHz.
Case ∅D×L=35×50, 40 ×40, 40 ×50, 40 ×70 and 40 ×100 mm.
handbook, 4 columns
MGB276
0 50 100
1
10
50 Tamb ( C)
o
4
10
2
0
Z
Z
10
1
1
2
3
4
1
2
3
Fig.16 Typical multiplier of impedance as a function of ambient temperature.
2000 Jan 18 14
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
handbook, 4 columns
106
MGB277
105
104
103
102
10 107
f (Hz)
102
10
1
Z
( )Ω
10 1
10 2
1
2
3
4
5
6
7
8
Fig.17 Typical impedance as a function of frequency.
Curve 1: 68 µF, 385 V.
Curve 2: 150 µF, 200 V.
Curve 3: 680 µF, 100 V.
Curve 4: 2200 µF, 63 V.
Curve 5: 3300 µF, 40 V.
Curve 6: 4700 µF, 25 V.
Curve 7: 6800 µF, 16 V.
Curve 8: 10000 µF, 10 V.
Case ∅D×L=25×30 mm.
Tamb =20°C.
Fig.18 Typical impedance as a function of frequency.
Curve 1: 100 µF, 385 V.
Curve 2: 220 µF, 200 V.
Curve 3: 1000 µF, 100 V.
Curve 4: 3300 µF, 63 V.
Curve 5: 4700 µF, 40 V.
Curve 6: 6800 µF, 25 V.
Curve 7: 10000 µF, 16 V.
Curve 8: 15000 µF, 10 V.
Case ∅D×L=25×40 mm.
Tamb =20°C.
handbook, 4 columns
106
MGB278
105
104
103
102
10 107
f (Hz)
102
10
1
Z
( )Ω
10 1
10 2
1
2
3
4
5
6
7
8
2000 Jan 18 15
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
Curve 1: 150 µF, 385 V.
Curve 2: 330 µF, 200 V.
Curve 3: 1500 µF, 100 V.
Curve 4: 4700 µF, 63 V.
Curve 5: 6800 µF, 40 V.
Curve 6: 10000 µF, 25 V.
Curve 7: 15000 µF, 16 V.
Curve 8: 22000 µF, 10 V.
Case ∅D×L=30×40 mm.
Tamb =20°C.
handbook, 4 columns
106
MGB279
105
104
103
102
10 107
f (Hz)
102
10
1
Z
( )Ω
10 1
10 2
1
2
3
4
5
6
7
8
Fig.19 Typical impedance as a function of frequency.
Curve 1: 220 µF, 385 V.
Curve 2: 470 µF, 200 V.
Curve 3: 2200 µF, 100 V.
Curve 4: 6800 µF, 63 V.
Curve 5: 10000 µF, 40 V.
Curve 6: 15000 µF, 25 V.
Curve 7: 22000 µF, 16 V.
Curve 8: 33000 µF, 10 V.
Case ∅D×L=35×40 mm.
Tamb =20°C.
handbook, 4 columns
106
MGB280
105
104
103
102
10 107
f (Hz)
102
10
1
Z
( )Ω
10 1
10 2
1
2
3
4
5
6
7
8
Fig.20 Typical impedance as a function of frequency.
2000 Jan 18 16
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
handbook, 4 columns
106
MGB281
105
104
103
102
10 107
f (Hz)
102
10
1
Z
( )Ω
10 1
10 2
1
2
3
4
5
6
7
8
Fig.21 Typical impedance as a function of frequency.
Curve 1: 330 µF, 385 V.
Curve 2: 680 µF, 200 V.
Curve 3: 3300 µF, 100 V.
Curve 4: 10000 µF, 63 V.
Curve 5: 15000 µF, 40 V.
Curve 6: 22000 µF, 25 V.
Curve 7: 33000 µF, 16 V.
Curve 8: 47000 µF, 10 V.
Case ∅D×L=35×50 and 40 ×40 mm.
Tamb =20°C.
Curve 1: 470 µF, 385 V.
Curve 2: 1000 µF, 200 V.
Curve 3: 4700 µF, 100 V.
Curve 4: 22000 µF, 40 V.
Curve 5: 33000 µF, 25 V.
Curve 6: 47000 µF, 16 V.
Curve 7: 68000 µF, 10 V.
Case ∅D×L=40×50 mm.
Tamb =20°C.
handbook, 4 columns
106
MGB282
105
104
103
102
10 107
f (Hz)
102
10
1
Z
( )Ω
10 1
10 2
1
2
3
4
5
6
7
Fig.22 Typical impedance as a function of frequency.
2000 Jan 18 17
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
handbook, 4 columns
106
MGB283
105
104
103
102
10 107
f (Hz)
102
10
1
Z
( )Ω
10 1
10 2
1
2
3
4
5
6
7
8
Fig.23 Typical impedance as a function of frequency.
Curve 1: 680 µF, 385 V.
Curve 2: 1500 µF, 200 V.
Curve 3: 6800 µF, 100 V.
Curve 4: 15000 µF, 63 V.
Curve 5: 33000 µF, 40 V.
Curve 6: 47000 µF, 25 V.
Curve 7: 68000 µF, 16 V.
Curve 8: 100000 µF, 10 V.
Case ∅D×L=40×70 mm.
Tamb =20°C.
handbook, 4 columns
106
MGB284
105
104
103
102
10 107
f (Hz)
102
10
1
Z
( )Ω
10 1
10 2
1
2
3
4
5
6
7
8
Fig.24 Typical impedance as a function of frequency.
Curve 1: 1000 µF, 385 V.
Curve 2: 2200 µF, 200 V.
Curve 3: 10000 µF, 100 V.
Curve 4: 22000 µF, 63 V.
Curve 5: 47000 µF, 40 V.
Curve 6: 68000 µF, 25 V.
Curve 7: 100000 µF, 16 V.
Curve 8: 150000 µF, 10 V.
Case ∅D×L=40×100 mm.
Tamb =20°C.
2000 Jan 18 18
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
RIPPLE CURRENT AND USEFUL LIFE
Table 4 Multiplier of ripple current (IR) as a function of frequency
FREQUENCY
(Hz) IR MULTIPLIER
50 0.83
100 1.00
200 1.10
400 1.15
1000 1.19
≥2000 1.20
Fig.25 Multiplier of useful life as a function of ambient temperature and ripple current load.
IA= actual ripple current at 100 Hz and 85 °C.
IR= rated ripple current at 100 Hz and 85 °C.
(1) Useful life at 85 °C and IR applied: 12000 hours.
handbook, full pagewidth
1.3
1.2
1.1
1.0
0.8
0.5
0.040 50 60 70 80 90
Tamb (C)
o
IA
R
I
MGA453
1.4
1.5
1.6
1.7
1.8
1.9
2.0
2.1
2.2
2.3
2.4
life multiplier
(1)
80
60
30
20
10
8
5
4
3
2
2.5
1.5
1
1.2
15
2000 Jan 18 19
BC Components Product specification
Aluminum electrolytic capacitors
Power Economic Printed Wiring 051/053 PEC-PW
SPECIFIC TESTS AND REQUIREMENTS
General tests and requirements are specified in this handbook, section
“Tests and Requirements”
.
Table 5 Test procedures and requirements
TEST PROCEDURE
(quick reference) REQUIREMENTS
NAME OF TEST REFERENCE
Endurance IEC 60384-4/
EN130300
subclause 4.13
Tamb =85°C; UR applied;
5000 hours UR≤100 V; ∆C/C: ±15%
UR>100 V; ∆C/C: ±10%
ESR ≤1.3 ×spec. limit
Z≤2×spec. limit
IL5 ≤spec. limit
Useful life CECC 30301
subclause 1.8.1 Tamb =85°C; UR and IR applied;
12000 hours UR≤100 V; ∆C/C: ±45%
UR>100 V; ∆C/C: ±30%
ESR ≤3×spec. limit
Z≤3×spec. limit
IL5 ≤spec. limit
no short or open circuit,
no visible damage
total failure percentage:
UR≤100 V: ≤1%;
UR>100 V: ≤3%
Shelf life
(storage at
high temperature)
IEC 60384-4/
EN130300
subclause 4.17
Tamb =85°C; no voltage applied;
500 hours
after test: URto be applied for 30 minutes,
24 to 48 hours before measurement
∆C/C: ±10%
ESR ≤1.2 ×spec. limit
IL5 ≤2×spec. limit
