After applying the pressure load of 5N for 10±1 seconds
horizontally to the center of capacitor side body which has no
electrode and has been soldered
beforehand on a substrate, there shall
be found neither exfoliation nor its sign
at the terminal electrode.
46.310
0G 0J 1A
SOLID TANTALUM ELECTROLYTIC CAPACITORS
F91
Type numbering system (Example : 10V 100µF)
Drawing
L
H
SS
W2
W1
(
mm
)
Case Code
C
N
LW1W2HS
6.0 ± 0.2
7.3 ± 0.2 3.2 ± 0.2
4.3 ± 0.2 2.2 ± 0.1
2.4 ± 0.1 2.5 ± 0.2
2.8 ± 0.2 1.3 ± 0.2
1.3 ± 0.2
Rated Capacitance (µF) Rated voltage (V)Rated voltage (V)
C Case N Case
68
10V
220
10V
Taping code
(Refer to page 333 for details)
F
19
21
31
4A
51
60
77
8M
9C
10 11
Case code
Capacitance tolerance
Rated capacitance Rated voltage
Series
Marking
Standard Ratings
LOW ESR
Resin-molded Chip
C •N Case
∗As for the surge and derated voltage at 125
˚C
, refer to page 332 for details.
Specifications
Performance Characteristics
Item
Category
Temperature Range --55 to +125
˚C
(Rated temperature : +85
˚C
)
Capacitance Tolerance
Dissipation Factor (120Hz)
ESR (100kHz)
±20%, ±10% (at 120Hz)
Refer to the table below.
Refer to the table below.
Leakage Current
•After 1 minute's application of rated voltage, leakage current
at 20
˚C
is not more than 0.01CV or 0.5µA, whichever is greater.
•After 1 minute's application of rated voltage, leakage current
at 85
˚C
is not more than 0.1CV or 5µA, whichever is greater.
•After 1 minute's application of derated voltage, leakage current
at 125
˚C
is not more than 0.125CV or 6.3µA, whichever is greater.
Capacitance Change
by Temperature
+15% Max. .(at +125
˚C
)
+10% Max. (at +85
˚C
)
--10% Max. (at --55
˚C
)
Damp Heat
(Steady State)
At 40˚C90 to 95% R.H. 500 hours (No voltage applied)
Capacitance Change Within ±10% of the initial value
Dissipation Factor......Initial specified value or less
Leakage Current........Initial specified value or less
Temperature Cycles
--55˚C / +125˚C30 minutes each 5 cycles
Capacitance Change Within ±5% of the initial value
Dissipation Factor......Initial specified value or less
Leakage Current........Initial specified value or less
Resistance
to Soldering Heat Capacitance Change Within ±5% of the initial value
Dissipation Factor......Initial specified value or less
Leakage Current........Initial specified value or less
10 seconds reflow at 260
˚C,
5 seconds immersion at 260
˚C
Surge∗
After application of surge in series with a 33
Ω
resistor at the rate of 30
seconds ON, 30 seconds OFF, for 1000 sucessive test cycles at 85
˚C
,
capacitors shall meet the characteristic requirements table below.
Capacitance Change....Within ±5% of the initial value
Dissipation Factor........Initial specified value or less
Leakage Current..........Initial specified value or less
Endurance∗
After 2000 hours' application of rated voltage in series with a 3
Ω
resistor
at 85
˚C
, or derated voltage in series with a 3
Ω
resistor at 125
˚C
,
capacitors shall meet the characteristics requirements table below.
Capacitance Change......Within ±10%of the initial value
Dissipation Factor..........Initial specified value or less
Leakage Current............Initial specified value or less
Shear Test
Terminal Strength
Keeping a capacitor surface-
mounted on a substrate upside down
and supporting the substrate at both
of the opposite bottom points 45mm
apart from the center of capacitor,
the pressure strength is applied with
a specified jig at the center of
substrate so that the substrate may bend by 1mm as illustrated.
Then, there shall be found no remarkable abnormality on the
capacitor terminals.
068
100
150
220
330
470
680
686
107
157
227
337
477
687
C
C
N
N
N
C
C
C • N
N
N
C
C
N
N
N
Code
Cap.
(
µ
F)
V
250
250
100
100
100
250
250
250
100
100
100
300
250
100
100
100
12
12
10
16
18
8
12
14
10
14
16
8
10
10
12
18
150
220
330
470
680
100
150
220
220
330
470
68
100
150
220
330
Part Number
6.0
8.8
13.2
18.8
27.2
6.3
9.5
13.9
13.9
20.8
29.6
6.8
10.0
15.0
22.0
33.0
Leakage
Current
(µA) ESR
(m
Ω
@100kHz)
Disspation
Factor
(%@120Hz)
Case
code
4V
6.3V
10V
Rated Volt
Rated
Capacitance
(µF)
F910G157MCC
F910G227MCC
F910G337MNC
F910G477MNC
F910G687MNC
F910J107MCC
F910J157MCC
F910J227MCC
F910J227MNC
F910J337MNC
F910J477MNC
F911A686MCC
F911A107MCC
F911A157MNC
F911A227MNC
F911A337MNC
C
C
N
N
N
C
C
C
N
N
N
C
C
N
N
N
Dimensions
In case of capacitance tolerance
±
10% type, K will be put at 9th digit of type numbering
system.
Compliant to the RoHS directive (2002/95/EC).
20
R230
45 45
1
mm
5N (0.51kg ¥f)
For 10±1 seconds
CAT.8100B
CAT.8100B
Case code L W1W2HS
P 2.0 ± 0.2 1.25 ± 0.1 0.9 ± 0.1 1.1 ± 0.1 0.5 ± 0.2
A 3.2 ± 0.2 1.6 ± 0.2 1.2 ± 0.1 1.1 ± 0.1 0.8 ± 0.2
B 3.4 ± 0.2 2.8 ± 0.2 2.3 ± 0.1 1.1 ± 0.1 0.8 ± 0.2
SOLID TANTALUM ELECTROLYTIC CAPACITORS
F92 Resin-molded Chip,
Compact Series
Capacitance code of “P” case products are as shown below.
Type numbering system(Example: 6.3V 10µF)
Drawing
Dimensions
Marking
Specifications Performance Characteristics
P Case A •B Case
Item
Category
Temperature Range –55 to +125
˚C
(Rated temperature : +85
˚C
)
Capacitance Tolerance ±20% (at 120Hz)
Leakage Current
•After 1 minute's application of rated voltage, leakage current
at 20
˚C
is not more than 0.01CV or 0.5µA, whichever is greater.
•After 1 minute's application of rated voltage, leakage current
at 85
˚C
is not more than 0.1CV or 5µA, whichever is greater.
•After 1 minute's application of derated voltage, leakage current
at 125
˚C
is not more than 0.125CV or 6.3µA, whichever is greater.
Capacitance Change
by Temperature
+20% Max. (at +125
˚C
)
+15% Max. (at +85
˚C
)
--15% Max. (at --55
˚C
)
+15% Max. (at +125
˚C
)
+10% Max. (at +85
˚C
)
--10% Max. (at --55
˚C
)
Damp Heat
(Steady State)
At 40˚C 90 to 95% R.H. 500 hours (No voltage applied)
Capacitance Change...
Refer to next page (
*
1
)
Dissipation Factor...150% or
Iess than the initial specified value
Leakage Current...
Initial specified value or less
Capacitance Change...
Refer to next page (
*
1
) Refer to next page (
*
1
)
Dissipation Factor...150% or
Iess than the initial specified value
Initial specified value or less
Leakage Current...
Initial specified value or less Initial specified value or less
Refer to next page (
*
1
)
Initial specified value or less
Initial specified value or less
Temperature Cycles
--55
˚C
/ +125
˚C
30 minutes each 5 cycles
(mm)
Taping code
(Refer to page 333 for details)
F
19
22
30
4J
51
60
76
8M
9P
10 11
Case code
Capacitance tolerance
Rated capacitance Rated voltage
Series
L
H
SS
W2
W1
Rated capacitance code
Rated voltage
(Voltage code)
P Case A Case B Case
Rated capacitance
(Capacitance code) Rated voltage (V)
Rated capacitance (µF)
AS G226 22
10V
4V G
J
A
V
6.3V
10V
35V16V C
D
E
20V
25V
Standard Ratings
Keeping a capacitor surface-mounted on a substrate upside
down and supporting the substrate at both of the opposite
bottom points 45mm apart from the center of capacitor, the
pressure strength is applied with a specified
jig at the center of substrate so that
the substrate may bend by 1mm as
illustrated.
Then, there shall be found no
remarkable abnormality on the
capacitor terminals.
∗As for the surge and derated voltage at 125
˚C
, refer to page 332 for details.
Capacitance Change
...
Refer to next page (
*
1
)
Dissipation Factor
...
150% of
Iess than the initial specified value
Leakage Current
...
Initial specified value or less
Refer to next page (
*
1
)
Initial specified value or less
Initial specified value or less
Capacitance Change
...
Refer to next page (
*
1
)
Dissipation Factor
...
150% or
less than the initial specified value
Leakage Current
...
Initial specified value or less
After 2000hours' application of
rated voltage in series with a
3
Ω
resistor at 85
˚C
, or derated
voltage in series with a 3
Ω
resistor at 125
˚C
, capacitors
shall meet the characteristic
requirements table below.
Capacitance Change
...
Refer to next page (
*
1
)
Dissipation Factor
...
150% or
less than the initial specified value
Leakage Current
...
Initial specified value or less
After 2000hours' application of
rated voltage in series with a
3
Ω
resistor at 85
˚C
, or derated
voltage in series with a 3
Ω
resistor at 125
˚C
, capacitors
shall meet the characteristic
requirements table below.
Capacitance Change
...
Refer to next page (
*
1
)
Dissipation Factor
...
Initial specified value or less
Leakage Current
...
Initial specified value or less
Refer to next page (
*
1
)
Initial specified value or less
Initial specified value or less
Resistance
to Soldering Heat
10 seconds reflow at 260
˚C
, 5 seconds immersion at 260
˚C
Surge∗
Endurance∗
After application of surge voltage in series with a 33
Ω
(For “P”case : 1k
Ω
)
resistor at the rate of 30 seconds ON, 30 seconds OFF, for 1000
successive test cycles at 85
˚C
, capacitors shall meet the characteristic
requirements table below.
After applying the pressure load of 5N for
10±1 seconds horizontally to the center
of capacitor side body which has no
electrode and has been soldered
beforehand on a substrate, there shall be
found neither exfoliation nor its sign at
the terminal electrode.
Terminal Strength
Shear Test
5N (0.51kg ¥f)
For 10 ± 1 seconds
20
R230
45 45
1
mm
Refer to Next Page
Dissipation Factor
(120Hz)
Refer to Next Page
ESR (100kHz)
( ) The series in parentheses are being developed. Please contact to your local Nichicon
sales office when these series are being designed in your application.
Compliant to the RoHS directive (2002/95/EC).
4 6.3 10 16 20 25 35
0G 0J 1A 1C 1D 1E 1V
0.22 224 AJ
0.33 334 AN
0.47 474 P P
•
AAS
0.68 684 P A W
1105 P P P
•
AP
•
AA A
1.5 155 P P A E
2.2 225 P P P
•
A(P)
•
AA
•
BB J
3.3 335 P P P
•
AA B N
4.7 475 P P P
•
A(P)
•
A
•
BA
•
BA
•
BS
6.8 685 P P P
•
AB w
10 106 P
•
AP
•
AP
•
AA
•
BB a
15 156 P P
•
AA e
22 226 P
•
AP
•
AA
•
BB
J
33 336 P
•
AA
•
BB n
47 476 (P)
•
A
•
BA
•
BB s
68 686 A
•
B
100 107 A
•
B(A)
•
B
150 157 B
220 227 (B)
Capacitance code
Cap.(
µ
F)
Code V
*1 : ∆C/C Marked "∗"
We can consider the type of compliance to AEC-Q200.
Please contact to your local Nichicon sales office
when these series are being designed in your application.
Item P Case (%) A , B Case(%)
Damp Heat ±20 ±10
Tempereature cycles ±10 ± 5
Resistance soldering heat
±10 ± 5
Surge ±10 ± 5
Endurance ±10 ±10
SOLID TANTALUM ELECTROLYTIC CAPACITORS
F92
Standard Ratings
1 P F921A105MPA 0.5 8 12.0 ∗
1.5 P F921A155MPA 0.5 8 12.0 ∗
2.2 P F921A225MPA 0.5 8 12.0 ∗
3.3 P F921A335MPA 0.5 8 12.0 ∗
3.3 A F921A335MAA 0.5 6 7.0 ∗
4.7 P F921A475MPA 0.5 8 6.0 ∗
4.7 A F921A475MAA 0.5 6 4.0 ∗
6.8 P F921A685MPA 0.7 8 6.0 ∗
6.8 A F921A685MAA 0.7 6 4.0 ∗
10 P F921A106MPA 1.0 14 6.0 ∗
10 A F921A106MAA 1.0 8 4.0 ∗
15 A F921A156MAA 1.5 8 4.0 ∗
22 A F921A226MAA 2.2 14 4.0 ±15
22 B F921A226MBA 2.2 8 1.9 ∗
33 B F921A336MBA 3.3 12 1.9 ∗
47 B F921A476MBA 4.7 18 1.9 ±15
2.2 P F920J225MPA 0.5 8 12.0 ∗
3.3 P F920J335MPA 0.5 8 12.0 ∗
4.7 P F920J475MPA 0.5 8 6.0 ∗
6.8 P F920J685MPA 0.5 10 6.0 ∗
10 P F920J106MPA 0.6 10 6.0 ∗
10 A F920J106MAA 0.6 8 4.0 ∗
15 P F920J156MPA 0.9 10 6.0 ∗
15 A F920J156MAA 0.9 8 4.0 ∗
22 P F920J226MPA 1.4 20 5.0 ∗
22 A F920J226MAA 1.4 12 2.8 ∗
33 A F920J336MAA 2.1 12 2.8 ∗
33 B F920J336MBA 2.1 12 1.7 ∗
47 A F920J476MAA 3.0 18 2.8 ±15
47 B F920J476MBA 3.0 12 1.7 ∗
100 B F920J107MBA 6.3 20 1.3 ±15
3.3 P F920G335MPA 0.5 8 12.0 ∗
4.7 P F920G475MPA 0.5 8 6.0 ∗
6.8 P F920G685MPA 0.5 10 6.0 ∗
10 P F920G106MPA 0.5 10 6.0 ∗
10 A F920G106MAA 0.5 8 4.0 ∗
15 P F920G156MPA 0.6 10 5.0 ∗
22 P F920G226MPA 0.9 20 5.0 ∗
22 A F920G226MAA 0.9 12 2.8 ∗
33 P F920G336MPA 1.3 20 4.0 ∗
33 A F920G336MAA 1.3 12 2.8 ∗
47 A F920G476MAA 1.9 18 2.8 ∗
47 B F920G476MBA 1.9 12 1.7 ∗
68 A F920G686MAA 2.7 25 2.8 ±15
68 B F920G686MBA 2.7 18 1.5 ∗
100 A F920G107MAA 4.0 30 2.8 ±15
100 B F920G107MBA 4.0 18 1.3 ∗
150 B F920G157MBA 6.0 25 1.3 ±15
4V
6.3
V
0.22 A F921V224MAA 0.5 4 10.0 ∗
0.33 A F921V334MAA 0.5 4 10.0 ∗
0.47 A F921V474MAA 0.5 4 10.0 ∗
1 A F921V105MAA 0.5 6 10.0 ∗
2.2 B F921V225MBA 0.8 6 4.0 ±10
3.3 B F921V335MBA 1.2 10 4.0 ±10
1 P F921E105MPA 0.5 8 20.0 ∗
1 A F921E105MAA 0.5 6 10.0 ∗
2.2 A F921E225MAA 0.6 8 10.0 ±15
2.2 B F921E225MBA 0.6 6 4.0 ∗
4.7 A F921E475MAA 1.2 10 7.0 ±10
4.7 B F921E475MBA 1.2 6 3.0 ∗
0.47 P F921D474MPA 0.5 8 20.0 ∗
0.47 A F921D474MAA 0.5 4 10.0 ∗
0.68 A F921D684MAA 0.5 4 10.0 ∗
1 P F921D105MPA 0.5 8 20.0 ∗
1 A F921D105MAA 0.5 4 10.0 ∗
1.5 A F921D155MAA 0.5 6 7.4 ∗
2.2 A F921D225MAA 0.5 6 7.0 ∗
4.7 A F921D475MAA 0.9 10 7.0 ±10
4.7 B F921D475MBA 0.9 6 3.0 ∗
10 B F921D106MBA 2.0 8 3.0 ±10
0.47 P F921C474MPA 0.5 8 20.0 ∗
0.68 P F921C684MPA 0.5 8 12.0 ∗
1 P F921C105MPA 0.5 8 12.0 ∗
1.5 P F921C155MPA 0.5 8 12.0 ∗
2.2 P F921C225MPA 0.5 8 12.0 ∗
2.2 A F921C225MAA 0.5 6 7.0 ∗
3.3 A F921C335MAA 0.5 6 7.0 ∗
4.7 A F921C475MAA 0.8 6 7.0 ∗
4.7 B F921C475MBA 0.8 6 3.0 ∗
6.8 B F921C685MBA 1.1 6 3.0 ∗
10 A F921C106MAA 1.6 8 7.0 ±15
10 B F921C106MBA 1.6 6 2.0 ∗
22 B F921C226MBA 3.5 12 2.0 ±15
10V
16V
20V
25V
35V
*1
∆C/C
(%)
Part Number
Leakage
Current
(
µ
A)
Disspation
Factor
(%@120Hz)
Case
code ESR
(
Ω
@100kHz)
Rated Volt
Rated
Capacitance
(
µ
F)
*1
∆C/C
(%)
Part Number
Leakage
Current
(
µ
A)
Disspation
Factor
(%@120Hz)
Case
code ESR
(
Ω
@100kHz)
Rated Volt
Rated
Capacitance
(
µ
F)
CAT.8100B
C
Performance Characteristics
Item
SOLID TANTALUM ELECTROLYTIC CAPACITORS
F93Resin-molded Chip,
Standard Series
∗As for the surge and derated voltage at 125
˚C
, refer to page 332 for details.
Type numbering system(Example: 10V 10µF)
Drawing
Dimensions
Marking
Specifications
Category
Temperature Range --55 to +125
˚C
(Rated temperature : +85
˚C
)
Capacitance Tolerance ±20%, ±10% (at 120Hz)
Dissipation Factor
(120Hz)
Refer to next page
ESR (100kHz) Refer to next page
Leakage Current
•
After 1 minute's application of rated voltage, leakage current
at 20
˚C
is not more than 0.01CV or 0.5µA, whichever is greater.
•
After 1 minute's application of rated voltage, leakage current
at 85
˚C
is not more than 0.1CV or 5µA, whichever is greater.
•
After 1 minute's application of derated voltage, leakage current
at 125
˚C
is not more than 0.125CV or 6.3µA, whichever is greater.
Capacitance Change
by Temperature +15% Max. (at +125
˚C
)
+10% Max. (at +85
˚C
)
--10% Max. (at --55
˚C
)
Damp Heat
(Steady State)
At 40
˚C
90 to 95% R.H. 500 hours (No voltage applied)
Capacitance Change...Refer to next page (* 1)
Dissipation Factor........Initial specified value or less
Leakage Current..........Initial specified value or less
Temperature Cycles
--55
˚C
/ +125
˚C
30 minutes each 5 cycles
Capacitance Change...Refer to next page (* 1)
Dissipation Factor........Initial specified value or less
Leakage Current..........Initial specified value or less
Resistance
to Soldering Heat
10 seconds reflow at 260
˚C ,
5 seconds immersion at 260
˚C
Capacitance Change...Refer to next page (* 1)
Dissipation Factor........Initial specified value or less
Leakage Current..........Initial specified value or less
Surge∗
After application of surge voltage in series with a 33Ωresistor at the rate of
30 seconds ON, 30 seconds OFF, for 1000 successive test cycles at
85
˚C
,capacitors shall meet the characteristic requirements table below.
Capacitance Change.....Refer to next page (* 1)
Dissipation Factor.........Initial specified value or less
Leakage Current...........Initial specified value or less
Endurance∗
After 2000 hours' application of rated voltage in series with a 3
Ω
resistor
at 85
˚C
, or derated voltage in series with a 3
Ω
resistor at 125
˚C
,
capacitors shall meet the characteristic requirements table below.
Capacitance Change......Refer to next page (* 1)
Dissipation Factor..........Initial specified value or less
Leakage Current............Initial specified value or less
Shear Test
After applying the pressure load of 5N for 10±1 seconds
horizontally to the center of capacitor side body which has no
electrode and has been soldered
beforehand on a substrate, there shall be
found neither exfoliation nor its sign at the
terminal electrode.
Terminal Strength
Keeping a capacitor surface-mounted on a substrate upside down
and supporting the substrate at both of the opposite bottom points
45mm apart from the center of
capacitor, the pressure strength is
applied with a specified jig at the
center of substrate so that the
substrate may bend by 1mm as
illustrated. Then, there shall be found
no remarkable abnormality on the
capacitor terminals.
Case code L W1W2HS
A 3.2±0.2 1.6±0.2 1.2±0.1 1.6±0.2 0.8±0.2
B 3.5±0.2 2.8±0.2 2.2±0.1 1.9±0.2 0.8±0.2
C 6.0±0.2 3.2±0.2 2.2±0.1 2.5±0.2 1.3±0.2
N 7.3 ± 0.2 4.3 ± 0.2 2.4 ± 0.1 2.8 ± 0.2 1.3 ± 0.2
(mm)
( ) The series in parentheses are being developed.
Please contact to your local Nichicon sales office when these
series are being designed in your application.
Taping code
(Refer to page 333 for details)
F
19
23
31
4A
51
60
76
8M
9A
10 11
Case code
Capacitance tolerance
Rated capacitance Rated voltage
Series
L
H
SS
W2
W1
L
H
SS
W2
W1
A •B Case C•N Case
Capacitance (µF)
Rated voltage (V)Rated voltage (V)
A Case B Case C Case N Case
(Rated voltage code) (Capacitance code)
C685 22
16V
47
16V
100
16V
G
J
A
4V
6.3V
10V
16V
20V D
E
V
25V
35V
5N (0.51kg ¥f)
For 10±1 seconds
20
R230
45 45
1
mm
Standard Ratings
Compliant to the RoHS directive (2002/95/EC).
0.68
1
1.5
2.2
3.3
4.7
6.8
10
15
22
33
47
68
100
150
220
330
470
680
684
105
155
225
335
475
685
106
156
226
336
476
686
107
157
227
337
477
687
A
A
A
A
A•B
B
(A) •B•C
C
N
N
A
A
A
A
A•B
A•B
A•B•C
B•C
B•C•N
N
N
A
A
A
A•B
A•B
A•B•C
B•C
B•C•N
C•N
N
N
A
A
A
A
A
A•B
A•B
A•B•C
B•C
(B) •C•N
N
C•N
N
N
A
A
A•B
A•B
A•B
C
B•C
C•N
C•N
(N)
A
A
A
A•B
B
B•C
C
C
N
N
4
0G 6.3
0J 10
1A 16
1C 20
1D 25
1E 35
1V
Cap.(
µ
F)
Code V
A
A
A
A
A•B
B•C
C
C•N
N
N
We can supply the type of compliance to AEC-Q200.
Please contact to your local Nichicon sales office
when these series are being designed in your application.
CAT.8100B
22 A F930G226MAA 0.9 6 2.5 ∗
33 A F930G336MAA 1.3 8 2.5 ∗
47 A F930G476MAA 1.9 18 2.5 ∗
68 A F930G686MAA 2.7 24 2.5 ∗
100 A F930G107MAA 4.0 30 2.0 ∗
100 B F930G107MBA 4.0 14 0.9 ∗
150 B F930G157MBA 6.0 16 0.7 ∗
220 B F930G227MBA 8.8 18 0.7 ∗
220 C F930G227MCC 8.8 12 0.7 ∗
330 C F930G337MCC 13.2 14 0.7 ∗
470 N F930G477MNC 18.8 16 0.3 ∗
680 N F930G687MNC 27.2 18 0.3 ∗
10 A F930J106MAA 0.6 6 3.0 ∗
15 A F930J156MAA 0.9 6 2.9 ∗
22 A F930J226MAA 1.4 8 2.5 ∗
33 A F930J336MAA 2.1 8 2.5 ∗
47 A F930J476MAA 3.0 18 2.5 ∗
47 B F930J476MBA 3.0 6 1.0 ∗
68 A F930J686MAA 4.3 20 2.0 ∗
68 B F930J686MBA 4.3 8 1.0 ∗
100 A F930J107MAA 6.3 35 2.0 ±15
100 B F930J107MBA 6.3 14 0.9 ∗
100 C F930J107MCC 6.3 8 0.7 ∗
150 B F930J157MBA 9.5 18 0.9 ∗
150 C F930J157MCC 9.5 12 0.7 ∗
220 B F930J227MBA 13.9 30 1.2 ±15
220 C F930J227MCC 13.9 14 0.7 ∗
220 N F930J227MNC 13.9 10 0.5 ∗
330 N F930J337MNC 20.8 14 0.5 ∗
470 N F930J477MNC 29.6 16 0.3 ∗
6.8 A F931A685MAA 0.7 6 3.5 ∗
10 A F931A106MAA 1.0 6 3.0 ∗
15 A F931A156MAA 1.5 8 2.9 ∗
22 A F931A226MAA 2.2 12 2.5 ∗
22 B F931A226MBA 2.2 6 1.9 ∗
33 A F931A336MAA 3.3 18 2.5 ∗
33 B F931A336MBA 3.3 8 1.4 ∗
47 A F931A476MAA 4.7 40 2.0 ±15
47 B F931A476MBA 4.7 8 1.0 ∗
47 C F931A476MCC 4.7 6 0.9 ∗
68 B F931A686MBA 6.8 12 0.9 ±15
68 C F931A686MCC 6.8 8 0.8 ∗
100 B F931A107MBA 10.0 18 1.2 ±15
100 C F931A107MCC 10.0 10 0.7 ∗
100 N F931A107MNC 10.0 8 0.6 ∗
150 C F931A157MCC 15.0 14 0.7 ∗
150 N F931A157MNC 15.0 10 0.6 ∗
220 N F931A227MNC 22.0 12 0.5 ∗
330 N F931A337MNC 33.0 18 0.5 ∗
4V
6.3
V
*1
∆C/C
(%)
Part Number
Leakage
Current
(
µ
A)
Disspation
Factor
(%@120Hz)
Case
code ESR
(
Ω
@100kHz)
Rated Volt
Rated
Capacitance
(
µ
F)
1 A F931C105MAA 0.5 4 7.5 ∗
2.2 A F931C225MAA 0.5 4 5.0 ∗
3.3 A F931C335MAA 0.5 4 4.5 ∗
4.7 A F931C475MAA 0.8 6 4.0 ∗
6.8 A F931C685MAA 1.1 6 3.5 ∗
10 A F931C106MAA 1.6 6 3.0 ∗
10 B F931C106MBA 1.6 6 2.0 ∗
15 A F931C156MAA 2.4 10 3.0 ∗
15 B F931C156MBA 2.4 6 2.0 ∗
22 A F931C226MAA 3.5 15 3.0 ±15
22 B F931C226MBA 3.5 8 1.9 ∗
22 C F931C226MCC 3.5 6 1.1 ∗
33 B F931C336MBA 5.3 8 1.9 ∗
33 C F931C336MCC 5.3 6 1.1 ∗
47 C F931C476MCC 7.5 8 0.9 ∗
47 N F931C476MNC 7.5 6 0.7 ∗
68 N F931C686MNC 10.9 6 0.6 ∗
100 C F931C107MCC 16.0 15 0.7 ±10
100 N F931C107MNC 16.0 10 0.6 ∗
150 N F931C157MNC 24.0 15 0.6 ∗
220 N F931C227MNC 35.2 25 0.7 ±10
2.2 A F931D225MAA 0.5 4 5.0 ∗
3.3 A F931D335MAA 0.7 4 4.5 ∗
4.7 A F931D475MAA 0.9 6 3.0 ∗
4.7 B F931D475MBA 0.9 6 2.8 ∗
6.8 A F931D685MAA 1.4 6 3.5 ∗
6.8 B F931D685MBA 1.4 6 2.5 ∗
10 A F931D106MAA 2.0 8 3.5 ∗
10 B F931D106MBA 2.0 6 2.1 ∗
15 C F931D156MCC 3.0 6 1.2 ∗
22 B F931D226MBA 4.4 8 1.9 ∗
22 C F931D226MCC 4.4 8 1.1 ∗
33 C F931D336MCC 6.6 8 1.1 ∗
33 N F931D336MNC 6.6 6 0.7 ∗
47 C F931D476MCC 9.4 10 1.1 ∗
47 N F931D476MNC 9.4 8 0.7 ∗
1 A F931E105MAA 0.5 4 7.5 ∗
1.5 A F931E155MAA 0.5 4 6.7 ∗
2.2 A F931E225MAA 0.6 6 6.3 ∗
3.3 A F931E335MAA 0.8 6 6.0 ∗
4.7 A F931E475MAA 1.2 8 4.0 ∗
4.7 B F931E475MBA 1.2 6 2.8 ∗
10 B F931E106MBA 2.5 12 1.9 ∗
10 C F931E106MCC 2.5 6 1.5 ∗
15 C F931E156MCC 3.8 8 1.2 ∗
22 C F931E226MCC 5.5 8 1.1 ∗
22 N F931E226MNC 5.5 6 0.7 ∗
33 N F931E336MNC 8.3 8 0.7 ∗
47 N F931E476MNC 11.8 8 0.7 ∗
0.68 A F931V684MAA 0.5 4 7.6 ∗
1 A F931V105MAA 0.5 4 7.5 ∗
1.5 A F931V155MAA 0.5 6 7.5 ∗
2.2 A F931V225MAA 0.8 6 7.0 ∗
2.2 B F931V225MBA 0.8 4 3.8 ∗
3.3 B F931V335MBA 1.2 4 3.5 ∗
4.7 B F931V475MBA 1.6 8 3.1 ∗
4.7 C F931V475MCC 1.6 6 1.8 ∗
6.8 C F931V685MCC 2.4 6 1.8 ∗
10 C F931V106MCC 3.5 6 1.6 ∗
15 N F931V156MNC 5.3 6 0.7 ∗
22 N F931V226MNC 7.7 8 0.7 ∗
20V
25V
35
V
*1
∆C/C
(%)
Part Number
Leakage
Current
(
µ
A)
Disspation
Factor
(%@120Hz)
Case
code ESR
(
Ω
@100kHz)
Rated Volt
Rated
Capacitance
(
µ
F)
10
V
16
V
SOLID TANTALUM ELECTROLYTIC CAPACITORS
F93
Standard Ratings
In case of capacitance tolerance ±10% type, K will be put at 9th digit of type
numbering system.
*1 : ∆C/C Marked "∗"
I t e m A • B • C • N Case (%)
Damp Heat ±10
Tempereature cycles ±5
Resistance soldering heat
±5
Surge ±5
Endurance ±10
CAT.8100B
SOLID TANTALUM ELECTROLYTIC CAPACITORS
Standard ratings
∗
As for the surge and derated voltage at 125
˚C
, refer to page 332 for details.
5N (0.51kg • f)
For 10 ± 1 seconds
F97Resin-molded Chip,
High Reliability
(High temperature /
moisture resistance) Series
Type numbering system (Example : 16V 3.3µF)
Dimensions
Marking
Drawing
Specifications
Taping code
(Refer to page 333 for details)
F
19
27
31
4C
53
63
75
8M
9A
10 11
Case code
Capacitance tolerance
Rated capacitance Rated voltage
Series
C • N CaseA • B Case
L
H
S
W1
W2
S
L
H
S
W1
W2
S
A Case B Case C Case
C475 10
16r
10
16r
Rated voltage
(Voltage code)Rated Capacitance
(Capacitance code )Rated voltage (V)Rated Capacitance (µF)
Rated Voltage (V)
Month code
Month code
N Case
47
10r
Case code
A
B
C
N
LW
1W2HS
(mm)
3.2 ± 0.2
3.5 ± 0.2
6.0 ± 0.2
7.3 ± 0.2
1.6 ± 0.2
2.8 ± 0.2
3.2 ± 0.2
4.3 ± 0.2
1.2 ± 0.1
2.2 ± 0.1
2.2 ± 0.1
2.4 ± 0.1
1.6 ± 0.2
1.9 ± 0.2
2.5 ± 0.2
2.8 ± 0.2
0.8 ± 0.2
0.8 ± 0.2
1.3 ± 0.2
1.3 ± 0.2
Item
--55 to +125
˚C
(Rated temperature : +85
˚C
)
Category
Temperature Range
Capacitance Tolerance
Performance Characteristics
±20%, ±10% (at 120Hz)
Leakage Current
∗
•
After 1 minute' s application of rated voltage,leakage current at 20˚C
is not more than 0.01CV or 0.5
µ
A, whichever is greater.
•
After 1 minute' s application of rated voltage,leakage current at 85˚C
is not more than 0.1CV or 5
µ
A,whichever is greater.
•
After 1 minute' s application of derated voltage,leakage current at
125˚Cis not more than 0.125CV or 6.3
µ
A,whichever is greater.
Capacitance Change
by Temperature
+15% Max. (at +125
˚C
)
+10% Max. (at +85
˚C
)
--10% Max. (at --55
˚C
)
Damp Heat
(Steady State)
At 85
˚C
, 85% R.H.,For 1000 hours (No voltage applied)
Capacitance Change •••••• Within ± 10% of the initial value
Dissipation Factor ••••••••••• Initial specified value or less
Leakage Current ••••••••••••
125% or less than the initial specified value
Load Humidity
After 500 hour' s application of rated voltage in series with a 33
Ω
resistor at 60
˚C
, 90 to 95
%
R.H.,
capacitor
s meet the characteristics
requirements table below.
Capacitance Change •••••• Within ±10% of the initial value
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current ••••••••••••
125% or less than the initial specified value
Temperature Cycles
At--55
˚C
/ +125
˚C
,For 30 minutes each,1000 cycles
Capacitance Change •••••• Within ±5% of the initial value
Dissipation Factor ••••••••••• Initial specified value or less
Leakage Current ••••••••••••• Initial specified value or less
Resistance
to Soldering Heat
10 seconds reflow at 260
˚C
, 5 seconds immersion at 260
˚C
.
Capacitance Change •••••• Within ±5% of the initial value
Dissipation Factor ••••••••••• Initial specified value or less
Leakage Current ••••••••••••• Initial specified value or less
Solderability After immersing capacitors completely into a solder pot at
245
˚C
for 2 to 3 seconds,more than 3/4 of their electrode area
shall remain covered with new solder.
Surge∗
After application of surge in series with a 33
Ω
resistor at the
rate of 30 seconds ON, 30 seconds OFF,for 1000 successive
test cycles at 85
˚C
,capacitors shall meet the characteristic
requirements table below.
Capacitance Change •••••• Within ±5% of the initial value
Dissipation Factor ••••••••••• Initial specified value or less
Leakage Current ••••••••••••• Initial specified value or less
Endurance∗
After 2000 hours' application of rated voltage in series with a
3
Ω
resistor at 85
˚C
,or derated voltage in series with a 3
Ω
resistor at 125
˚C
,capacitors shall meet the characteristic
requirements table below.
Capacitance Change •••••• Within ±10% of the initial value
Dissipation Factor ••••••••••• Initial specified value or less
Leakage Current ••••••••••••• Initial specified value or less
Shear Test
After applying the pressure load of 5N
for 10 ± 1 seconds horizontally to the
center of capacitor side body which
has no electrode and has been
soldered beforehand on a substrate,
there shall be found neither exfoliation
nor its sign at the terminal electrode.
Terminal Strength
Keeping a capacitor surface-mounted on a substrate upside
down and supporting the substrate at both of the opposite
bottom points 45mm apart from the center of capacitor, the
pressure strength is applied with a
specified jig at the center of the
substrate so that substrate may
bend by1mm as illustrated.
Then, there shall be found no
remarkable abnormality on the
capacitor terminals.
45 45
R230 20
1mm
Dissipation Factor
Refer to next page
ESR (100kHz) Refer to next page
Compliant to the RoHS directive (2002/95/EC).
Compliant to AEC-Q200.
6.3 10 16 20 25 35
0J 1A 1C 1D 1E 1V
0.47 474 A
0.68 684 A A A
1 105 A A (A)
1.5 155 A A (A) •B
2.2 225 A A A (A) •BB
3.3335AAABB(B)
•C
4.7 475 A A •BA
•BA
•B(B)
•CC
6.8 685 A •BB B(B)
•C C (C) •N
10 106 A •BA
•B•C(B)
•CC
•NN
15 156 B B (B) •C N (C) •N
22 226 A •BA
•BB
•C•NC
•N (N)
33 336 A •CB
•C•NB
•C•N (N)
47 476 B •C(B)
•C•N (C) •N
68 686 N N
100 107 N (C) •(N)
Cap.(
µ
F)
V
Code
( ) The series in parentheses are being developed.
Please contact to your local Nichicon sales office when these
series are being designed in your application.
Applications
Automotive electronics(Engine ECU)
Industrial equipment
CAT.8100B
Standard Ratings
SOLID TANTALUM ELECTROLYTIC CAPACITORS
F97
In case of capacitance tolerance ±10% type, K will be put at 9th digit of type
numbering system.
2.2 A F971A225MAA 0.5 4 5.0
3.3 A F971A335MAA 0.5 4 4.5
4.7 A F971A475MAA 0.5 6 4.0
4.7 B F971A475MBA 0.5 6 2.8
6.8 B F971A685MBA 0.7 6 2.5
10 A F971A106MAA 1.0 6 3.0
10 B F971A106MBA 1.0 6 2.0
15 B F971A156MBA 1.5 6 2.0
22 A F971A226MAA 2.2 15 3.0
22 B F971A226MBA 2.2 8 1.9
33 B F971A336MBA 3.3 8 1.9
33 C F971A336MCC 3.3 6 1.1
33 N F971A336MNC 3.3 6 0.7
47 C F971A476MCC 4.7 8 0.9
47 N F971A476MNC 4.7 6 0.7
68 N F971A686MNC 6.8 6 0.6
1.5 A F971C155MAA 0.5 4 6.3
2.2 A F971C225MAA 0.5 4 5.0
3.3 A F971C335MAA 0.5 4 4.5
4.7 A F971C475MAA 0.8 8 4.0
4.7 B F971C475MBA 0.8 6 2.8
6.8 B F971C685MBA 1.1 6 2.5
10 A F971C106MAA 1.6 8 3.5
10 B F971C106MBA 1.6 6 2.1
10 C F971C106MCC 1.6 6 1.5
15 C F971C156MCC 2.4 6 1.2
22 B F971C226MBA 3.5 8 1.9
22 C F971C226MCC 3.5 8 1.1
22 N F971C226MNC 3.5 6 0.7
33 B F971C336MBA 5.3 10 2.1
33 C F971C336MCC 5.3 8 1.1
33 N F971C336MNC 5.3 6 0.7
47 N F971C476MNC 7.5 8 0.7
0.68 A F971D684MAA 0.5 4 7.6
1 A F971D105MAA 0.5 4 7.5
1.5 A F971D155MAA 0.5 4 6.7
2.2 A F971D225MAA 0.5 6 6.3
3.3 B F971D335MBA 0.7 4 3.1
4.7 A F971D475MAA 0.9 8 4.0
4.7 B F971D475MBA 0.9 6 2.8
6.8 C F971D685MCC 1.4 6 1.8
10 C F971D106MCC 2.0 6 1.5
15 N F971D156MNC 3.0 6 0.7
22 C F971D226MCC 4.4 8 1.1
22 N F971D226MNC 4.4 6 0.7
3.3 A F970J335MAA 0.5 4 4.5
4.7 A F970J475MAA 0.5 6 4.0
6.8 A F970J685MAA 0.5 6 3.5
6.8 B F970J685MBA 0.5 6 2.5
15 B F970J156MBA 0.9 6 2.0
22 A F970J226MAA 1.4 12 2.5
22 B F970J226MBA 1.4 8 1.9
33 A F970J336MAA 2.1 12 2.5
33 C F970J336MCC 2.1 6 1.1
47 B F970J476MBA 3.0 8 1.0
47 C F970J476MCC 3.0 6 0.9
68 N F970J686MNC 4.3 6 0.6
100 N F970J107MNC 6.3 8 0.6
Part Number
Leakage
Current
(
µ
A)
Disspation
Factor
(%@120Hz)
Case
code ESR
(
Ω
@100kHz)
6.3
V
10
V
16
V
20
V
Rated Volt
Rated
Capacitance
(
µ
F)
0.68 A F971E684MAA 0.5 4 7.6
1 A F971E105MAA 0.5 4 7.5
2.2 B F971E225MBA 0.6 4 3.8
3.3 B F971E335MBA 0.8 4 3.5
4.7 C F971E475MCC 1.2 6 1.8
6.8 C F971E685MCC 1.7 6 1.8
10 C F971E106MCC 2.5 6 1.6
10 N F971E106MNC 2.5 6 1.0
15 N F971E156MNC 3.8 6 0.7
0.47 A F971V474MAA 0.5 4 10.0
0.68 A F971V684MAA 0.5 4 7.6
1.5 B F971V155MBA 0.5 4 4.0
2.2 B F971V225MBA 0.8 4 3.8
3.3 C F971V335MCC 1.2 4 2.0
4.7 C F971V475MCC 1.6 6 1.8
6.8 N F971V685MNC 2.4 6 1.0
10 N F971V106MNC 3.5 6 1.0
Part Number
Leakage
Current
(
µ
A)
Disspation
Factor
(%@120Hz)
Case
code ESR
(
Ω
@100kHz)
35V
25V
Rated Volt
Rated
Capacitance
(
µ
F)
CAT.8100B
SOLID TANTALUM ELECTROLYTIC CAPACITORS
After applying the pressure load of 5N
for 10±1 seconds horizontally to the
center of capacitor side body which has
no electrode and has been soldered
beforehand on a substrate, there shall be
found neither exfoliation
nor its sign at the terminal electrode.
Refer to next page
Provided that
•After 1 minute's application of rated voltage, leakage current at 85˚C,
10 times or less than 20˚C specified value.
•After 1 minute's application of rated voltage, leakage current at 125
˚C,
12.5 times or less than 20˚C specified value.
+15% Max. (at +125
˚C
)
+10% Max. (at +85
˚C
)
--10% Max. (at --55
˚C
)
Damp Heat
(Steady State)
Temperature Cycles
At 40
˚C
, 90 to 95% R.H., For 500 hours (No voltage applied)
Capacitance Change •••••• Refer to next page (*1)
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current •••••••••••• Initial specified value or less
At --55
˚C
/ +125
˚C
, 30 minutes each, For 5 cycles,
Capacitance Change •••••• Refer to next page (*1)
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current •••••••••••• Initial specified value or less
Resistance to
Soldering Heat Capacitance Change ••••••••• Refer to next page (*1)
Dissipation Factor ••••••••••••• Initial specified value or less
Leakage Current ••••••••••••••• Initial specified value or less
Endurance∗
After 2000 hours' application of rated voltage at 85
˚C
,
capacitors shall meet the characteristic requirements table below.
Capacitance Change •••••• Refer to next page (*1)
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current •••••••••••• Initial specified value or less
Surge∗
After application of surge voltage in series with a 33
Ω
resistor at the rate of 30
seconds ON, 30 seconds OFF, for 1000 successive test cycles at 85
˚C
,
capacitors shall meet the characteristic requirements table below.
Capacitance Change •••••• Refer to next page (*1)
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current •••••••••••• Initial specified value or less
Shear Test
Terminal Strength
Keeping a capacitor surface-mounted on a substrate upside
down and supporting the substrate at both of the opposite
bottom points 45mm apart from the center of capacitor,
the pressure strength is applied with
a specified jig at the center of
substrate so that the substrate may
bend by 1mm as illustrated. Then,
there shall be found no remarkable
abnormality on the capacitor terminals.
5N (0.51kg • f)
For 10 ± 1 seconds
MUSE
F95
Conformal coated Chip, For Mobile Audio Specifications
Type numbering system (Example : 4V 220µF)
Drawing
L W
H
Solder electrode electrode
Solder
ABC(D)
Resin
Single-side electrodes
(Both electrodes at bottom side only)
Item
Category
Temperature Range
Capacitance Tolerance
Dissipation Factor
(at 120Hz)
Leakage Current
Capacitance Change
by Temperature
Performance Characteristics
--55 to +125
˚C
(Rated temperature : +85
˚C
)
±20%, ±10% (at 120Hz)
D dimension only for reference
Dimensions
Refer to next page
R230
45 45
20
1
mm
∗As for the surge voltage, refer to page 332 for details.
(mm)
Refer to next pageESR(100kHz)
Taping code
(Refer to page 333 for details)
Single face
electrode
MUSE series code
F
19
25
30
4G
52
62
77
8M
9S
10 11 A
12 M
13 Q
15 2
16
1
14
Case code
Capacitance tolerance
Rated capacitance
Rated voltage
Series
Case code LWHABC( D )
3.2 ± 0.3 1.6 ± 0.3 1.0 ± 0.2 0.8 ± 0.3 1.2 ± 0.3 0.8 ± 0.3 (0.2)
S2.2 ± 0.3 1.25 ± 0.3 1.0 ± 0.2 0.6 ± 0.3 0.8 ± 0.3 0.8 ± 0.3 (0.2)
P
1.4 ± 0.2
1.0 ± 0.2 0.8 ± 0.3
0.8 ± 0.2 1.2 ± 0.3
1.2 ± 0.2 0.8 ± 0.3
1.1 ± 0.2
1.7 ± 0.3
2.7 ± 0.2
3.2 ± 0.3
3.5 ± 0.2 (0.2)
(0.2)
A
T1.8 ± 0.2 0.8 ± 0.3 1.2 ± 0.3 1.1 ± 0.32.8 ± 0.23.5 ± 0.2 (0.2)
B
Applications
Mobile Audio Player Mobile phone
Smartphone Wireless Microphone System
Feature
Rich sound in the bass register and clear sound,Materials
are strictly selected to achieve high level sound.
F95 series has no lead-frame, and no vibration factor.
Low ESR, Low ESL
Line up miniature size and high capacitance, necessary to
mobile design.
10 seconds reflow at 260˚C, 10 seconds immersion at 260˚C
Compliant to the RoHS directive (2002/95/EC).
CAT.8100B
SOLID TANTALUM ELECTROLYTIC CAPACITORS
( ) The series in parentheses are being developed.
Please contact to your local Nichicon sales office when
these series are being designed in your application.
P case - No marking on part.
MarkingStandard Ratings
Rated Capacitance code
S•A case T•B Case
J8
J8
µF
code 68
W7 100
A8 150
E8 220
J8 330
N8 470
S8 680
W8
Standard Ratings
*1 : ∆C/C Marked "∗"
*2 : Leakage Current
After 1 minute's application of rated voltage, leakage current at
20
˚C.
I t e m S • A • T • B Case (%)
Damp Heat ±10
Tempereature cycles ±5
Resistance soldering heat
±5
Surge ±5
Endurance ±10
MUSE
F95
4 6.3 10
0G 0J 1A
68 686 S S B
100 107 S S • TB
150 157 S (A)
220 227 (P) • S • T (A) • (T) • B
330 337 T B
470 477 (T) • B (B)
680 687 (T) • (B)
V
Cap.
(µF) Code
68 S
F950G686MSAAM1Q2
2.7 10 0.8 ∗
100 S
F950G107MSAAM1Q2
4.0 14 0.8 ∗
150 S
F950G157MSAAM1Q2
6.0 22 0.8 ±15
220 S
F950G227MSAAM1Q2
8.8 30 0.8 ±15
220 T
F950G227MTAAM1Q2
8.8 25 0.6 ∗
330 T
F950G337MTAAM1Q2
13.2 40 0.8 ±20
470 B
F950G477MBAAM1Q2
18.8 40 0.4 ±20
68 S
F950J686MSAAM1Q2
4.3 14 0.9 ∗
100 S
F950J107MSAAM1Q2
6.3 20 0.9
±15
100 T
F950J107MTAAM1Q2
6.3 14 0.6 ∗
220 B
F950J227MBAAM1Q2
13.9 30 0.4 ∗
330 B
F950J337MBAAM1Q2
20.8 35 0.6 ±20
68 B
F951A686MBAAM1Q2
6.8 12 0.4 ∗
100 B
F951A107MBAAM1Q2
10.0 14 0.4 ∗
4V
6.3V
10V
*1
∆C/C
(%)
Part Number
*2
Leakage Current
(
µ
A)
Disspation
Factor
(%@120Hz)
Case
code ESR
(
Ω
@100kHz)
Rated Volt
Rated
Capacitance
(
µ
F)
In case of capacitance tolerance
±
10% type, K will be put at 9th digit of type numbering
system.
CAT.8100B
Type numbering system (Example : 4V 330µF)
Drawing
L W
H
Solder electrode electrode
Solder
ABC(D)
Resin
Single-side electrodes
(Both electrodes at bottom side only)
Taping code
(Refer to page 333 for details)
Single face electrode
F
19
25
30
4G
53
63
77
8M
9A
10 11 A
12 Q
13 2
14
Case code
Capacitance tolerance
Rated capacitance Rated voltage
Series
After applying the pressure load of 5N
for 10±1 seconds horizontally to the
center of capacitor side body which has
no electrode and has been soldered
beforehand on a substrate, there shall be
found neither exfoliation
nor its sign at the terminal electrode.
Refer to next page
Provided that
•After 1 minute's application of rated voltage, leakage current at 85
˚C,
10 times or less than 20˚C specified value.
•After 1 minute's application of rated voltage, leakage current at 125
˚C,
12.5 times or less than 20˚C specified value.
10 seconds reflow at 260˚C, 10 seconds immersion at 260˚C
+15% Max. (at +125
˚C
)
+10% Max. (at +85
˚C
)
--10% Max. (at --55
˚C
)
Damp Heat
(Steady State)
Temperature Cycles
At 40
˚C
, 90 to 95% R.H., For 500 hours (No voltage applied)
Capacitance Change ••••••
Refer to next page (
*
1
)
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current •••••••••••• Initial specified value or less
At --55
˚C
/ +125
˚C
, 30 minutes each, For 5 cycles,
Capacitance Change ••••••
Refer to next page (
*
1
)
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current •••••••••••• Initial specified value or less
Resistance to
Soldering Heat Capacitance Change ••••••
Refer to next page (
*
1
)
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current •••••••••••• Initial specified value or less
Endurance∗
After 2000 hours' application of rated voltage at 85
˚C
,
capacitors shall meet the characteristic requirements table below.
Capacitance Change ••••••
Refer to next page (
*
1
)
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current •••••••••••• Initial specified value or less
Surge∗
After application of surge voltage in series with a 33
Ω
resistor at the rate of 30
seconds ON, 30 seconds OFF, for 1000 successive test cycles at 85
˚C
,
capacitors shall meet the characteristic requirements table below.
Capacitance Change ••••••
Refer to next page (
*
1
)
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current •••••••••••• Initial specified value or less
Shear Test
Terminal Strength
Keeping a capacitor surface-mounted on a substrate upside
down and supporting the substrate at both of the opposite
bottom points 45mm apart from the center of capacitor,
the pressure strength is applied with
a specified jig at the center of
substrate so that the substrate may
bend by 1mm as illustrated. Then,
there shall be found no remarkable
abnormality on the capacitor terminals.
5N (0.51kg • f)
For 10 ± 1 seconds
SOLID TANTALUM ELECTROLYTIC CAPACITORS
F95 Conformal coated
Chip
Specifications
Item
Category
Temperature Range
Capacitance Tolerance
Dissipation Factor
(at 120Hz)
Leakage Current
Capacitance Change
by Temperature
Performance Characteristics
--55 to +125
˚C
(Rated temperature : +85
˚C
)
±20%, ±10% (at 120Hz) (However R •P Case ±20%)
D dimension only for reference
( ) The series in parentheses are being developed.
Please contact to your local Nichicon sales office when
these series are being designed in your application.
Dimensions
Refer to next page
R230
45 45
20
1
mm
∗As for the surge voltage, refer to page 332 for details.
Standard Ratings
(mm)
Refer to next pageESR(100kHz)
Case code L
2.2 ± 0.3 1.25 ± 0.3 1.0 ± 0.2 0.6 ± 0.3 0.8 ± 0.3 0.8 ± 0.3
W H A B C ( D )
(0.2)
P2.2 ± 0.3 1.25 ± 0.3 0.65MAX. 0.6 ± 0.3 0.8 ± 0.3 0.5MIN (0.2)
R
3.2 ± 0.2 1.6 ± 0.2 0.8 ± 0.2 0.8 ± 0.2 1.2 ± 0.2 0.8 ± 0.2 (0.2)
Q3.2 ± 0.3 1.6 ± 0.3 1.0 ± 0.2 0.8 ± 0.3 1.2 ± 0.3 0.8 ± 0.3 (0.2)
S1.4 ± 0.2
1.0 ± 0.2 0.8 ± 0.3
0.8 ± 0.2 1.2 ± 0.3
1.2 ± 0.2 0.8 ± 0.3
1.1 ± 0.2
1.7 ± 0.3
2.7 ± 0.2
3.2 ± 0.3
3.5 ± 0.2 (0.2)
(0.2)
A
T1.8 ± 0.2 0.8 ± 0.3 1.2 ± 0.3 1.1 ± 0.32.8 ± 0.23.5 ±0.2 (0.2)
B
Compliant to the RoHS directive (2002/95/EC).
1
1.5
2.2
3.3
4.7
6.8
10
15
22
33
47
68
100
150
220
330
470
680
105
155
225
335
475
685
106
156
226
336
476
686
107
157
227
337
477
687
(R)
P•S•A
P•B
(P)
•
Q
•
S
•
A
•
T
•
B
(P) •(S) •A•T•B
(P) •(A) •(T) •B
(T)
R
(R) •P
P
P
P
•
Q
•
S
•
A
•
T
•
B
B
(S) • (A) •(T) •B
B
(B)
R•P
P
P•Q•S•A
P•Q•S•A
P
•
(
Q)
•
S
•
A
•
T
•
B
B
(S) •A•T•B
R•P
P•Q•S•A
S•A
Q•S•A•T•B
(A) •T•B
B
P
S•A
S•A•B
B
P•S
A
B
4
0G 6.3
0J 10
1A 16
1C 20
1D 25
1E 35
1V
Cap.
(µF) Code V
R
R•P
P•Q•S•A
(Q) •(S)
A•(T) •B
Applications
Smartphone Wireless module
Tablet PC e-book
CAT.8100B
SOLID TANTALUM ELECTROLYTIC CAPACITORS
F95
Standard Ratings
In case of capacitance tolerance ±10% type, K will be put at 9th digit of type
numbering system.
*1 : ∆C/C Marked "∗"
I t e m P • Q • S • A • T • B Case (%)
Damp Heat ±10
Tempereature cycles ±5
Resistance soldering heat
±5
Surge ±5
Endurance ±10
10 R F951A106MRAAQ2 1.0 18 3.0 ±20
10 P F951A106MPAAQ2 1.0 8 3.0 ∗
15 P F951A156MPAAQ2 1.5 10 3.0 ∗
22 P F951A226MPAAQ2 2.2 14 3.0 ∗
22 Q F951A226MQAAQ2 2.2 10 2.0 ∗
22 S F951A226MSAAQ2 2.2 10 1.1 ∗
22 A F951A226MAAAQ2 2.2 6 0.9 ∗
33 P F951A336MPAAQ2 3.3 20 3.0 ±15
33 Q F951A336MQAAQ2 3.3 18 3.0 ±15
33 S F951A336MSAAQ2 3.3 10 1.1 ∗
33 A F951A336MAAAQ2 3.3 10 0.8 ∗
47 P F951A476MPAAQ2 4.7 30 3.0 ±20
47 S F951A476MSAAQ2 4.7 14 1.1 ±15
47 A F951A476MAAAQ2 4.7 10 0.8 ∗
47 T F951A476MTAAQ2 4.7 12 0.8 ∗
47 B F951A476MBAAQ2 4.7 8 0.4 ∗
68 B F951A686MBAAQ2 6.8 12 0.4 ∗
100 A F951A107MAAAQ2 10.0 35 1.0 ±15
100 T F951A107MTAAQ2 10.0 20 0.6 ±15
100 B F951A107MBAAQ2 10.0 14 0.4 ∗
22 R F950J226MRAAQ2 1.4 20 2.0 ±20
33 P F950J336MPAAQ2 2.1 14 1.1 ∗
47 P F950J476MPAAQ2 3.0 20 1.1 ±15
68 P F950J686MPAAQ2 4.3 25 1.2 ±15
100 P F950J107MPAAQ2 12.6 35 1.2 ±20
100 Q F950J107MQAAQ2 6.3 30 1.1 ±20
100 S F950J107MSAAQ2 6.3 20 0.9 ±15
100 A F950J107MAAAQ2 6.3 14 0.5 ∗
100 T F950J107MTAAQ2 6.3 14 0.6 ∗
100 B F950J107MBAAQ2 6.3 14 0.4 ∗
150 B F950J157MBAAQ2 9.5 18 0.4 ∗
220 B F950J227MBAAQ2 13.9 30 0.4 ∗
330 B F950J337MBAAQ2 20.8 35 0.6 ±20
100 P F950G107MPAAQ2 4.0 30 1.2 ±15
100 S F950G107MSAAQ2 4.0 14 0.8 ∗
100 A F950G107MAAAQ2 4.0 12 0.5 ∗
150 P F950G157MPAAQ2 12.0 31 1.1 ±20
150 B F950G157MBAAQ2 6.0 14 0.4 ∗
220 Q F950G227MQAAQ2 8.8 30 1.5 ±20
220 S F950G227MSAAQ2 8.8 30 0.8 ±15
220 A F950G227MAAAQ2 8.8 25 0.8 ±15
220 T F950G227MTAAQ2 8.8 25 0.6 ∗
220 B F950G227MBAAQ2 8.8 16 0.4 ∗
330 A F950G337MAAAQ2 13.2 40 0.8 ±20
330 T F950G337MTAAQ2 13.2 40 0.8 ±20
330 B F950G337MBAAQ2 13.2 30 0.6 ±15
470 B F950G477MBAAQ2 18.8 40 0.4 ±20
4V
6.3V
10V
16V
1 P F951V105MPAAQ2 0.5 8 10.0 ±10
1 S F951V105MSAAQ2 0.5 6 8.0
∗
2.2 A F951V225MAAAQ2 0.8 6 4.4 ∗
4.7 B F951V475MBAAQ2 1.7 6 1.6 ∗
1 R F951E105MRAAQ2 0.5 10 10.0 ±10
2.2 R F951E225MRAAQ2 0.6 15 15.0 ±20
2.2 P F951E225MPAAQ2 0.6 8 6.0 ±15
4.7 P F951E475MPAAQ2 1.2 10 8.0 ±15
4.7 Q F951E475MQAAQ2 1.2 10 4.0 ±15
4.7 S F951E475MSAAQ2 1.2 8 4.0
∗
4.7 A F951E475MAAAQ2 1.2 8 2.0 ∗
10 A F951E106MAAAQ2 2.5 12 2.0 ±15
10 B F951E106MBAAQ2 2.5 6 0.9 ∗
2.2 P F951D225MPAAQ2 0.5 6 6.0 ∗
4.7 S F951D475MSAAQ2 0.9 8 4.0 ∗
4.7 A F951D475MAAAQ2 0.9 6 1.5 ∗
10 S F951D106MSAAQ2 2.0 10 4.0 ±10
10 A F951D106MAAAQ2 2.0 8 1.5 ∗
10 B F951D106MBAAQ2 2.0 6 0.8 ∗
22 B F951D226MBAAQ2 4.4 8 0.8 ∗
4.7 R F951C475MRAAQ2 0.8 12 6.0 ±20
4.7 P F951C475MPAAQ2 0.8 10 4.0 ∗
10 P F951C106MPAAQ2 1.6 10 4.0 ∗
10 Q F951C106MQAAQ2 1.6 8 3.0 ∗
10 S F951C106MSAAQ2 1.6 8 2.0 ∗
10 A F951C106MAAAQ2 1.6 6 1.4 ∗
15 S F951C156MSAAQ2 2.4 8 2.0 ∗
15 A F951C156MAAAQ2 2.4 8 1.4
∗
22 Q F951C226MQAAQ2 3.5 12 3.0 ∗
22 S F951C226MSAAQ2 3.5 10 2.0 ±15
22 A F951C226MAAAQ2 3.5 8 1.4 ∗
22 T F951C226MTAAQ2 3.5 8 1.4 ∗
22 B F951C226MBAAQ2 3.5 6 0.5 ∗
33 T F951C336MTAAQ2 5.3 11 1.5 ±10
33 B F951C336MBAAQ2 5.3 8 0.5 ∗
47 B F951C476MBAAQ2 7.5 10 0.6 ∗
20V
25V
35V
*1
∆C/C
(%)
Part Number
Leakage Current
(
µ
A)
Disspation
Factor
(
%@120Hz
)
Case
code ESR
(
Ω
@100kHz)
Rated Volt
Rated
Capacitance
(
µ
F)
*1
∆C/C
(%)
Part Number
Leakage Current
(
µ
A)
Disspation
Factor
(
%@120Hz
)
Case
code ESR
(
Ω
@100kHz)
Rated Volt
Rated
Capacitance
(
µ
F)
*2 *2
*2 :
Leakage Current After 1 minute's application of rated voltage, leakage current at 20˚C.
CAT.8100B
Keeping a capacitor surface-mounted on a substrate upside
down and supporting the substrate at both of the opposite
bottom points 45mm apart from the center of capacitor,
the pressure strength is applied with
a specified jig at the center of
substrate so that the substrate may
bend by 1mm as illustrated. Then,
there shall be found no remarkable
abnormality on the capacitor terminals.
After applying the pressure load of 5N
for 10±1 seconds horizontally to the
center of capacitor side body which has
no electrode and has been soldered
beforehand on a substrate, there shall be
found neither exfoliation
nor its sign at the terminal electrode.
After 2000 hours' application of rated voltage at 85˚C,
capacitors shall meet the characteristic requirements table below.
Capacitance Change •••••• Refer to * 1
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current ••••••••••••Initial specified value or less
After application of surge in series with a 33Ωresistor at the rate of 30
seconds ON, 30 seconds OFF, for 1000 successive test cycles at 85˚C,
capacitors shall meet the characteristic requirements table below.
Capacitance Change •••••• Refer to * 1
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current ••••••••••••Initial specified value or less
At 40˚C, 90 to 95% R.H., For 500 hours (No voltage applied)
Capacitance Change •••••• Refer to * 1
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current ••••••••••• Initial specified value or less
+15% Max. (at +125˚C)
+10% Max. (at +85˚C)
--10% Max. (at --55˚C)
•After 1 minute's application of rated voltage, leakage current at 20˚C is not
more than 0.01CV or 0.5µA, whichever is greater.
•After 1 minute's application of rated voltage, leakage current at 85˚C is not
more than 0.1CV or 5µA, whichever is greater.
•After 1 minute's application of derated voltage, leakage current at 125˚Cis
not more than 0.125CV or 6.3µA, whichever is greater.
Refer to next page
Refer to next page
Leakage Current
5N (0.51kg • f)
For 10 ± 1 seconds
SOLID TANTALUM ELECTROLYTIC CAPACITORS
F72
Low Profile
Conformal
coated Chip
Specifications
Type numbering system (Example : 16V 150µF)
Drawing
Item
Category
Temperature Range
Capacitance Tolerance
Dissipation Factor
(120Hz)
ESR (100kHz)
Capacitance Change
by Temperature
Damp Heat
(Steady State)
Temperature Cycles
Resistance to
Soldering Heat
Surge∗
Endurance∗
Shear Test
Terminal Strength
Performance Characteristics
--55 to +125˚C (Rated temperature : +85˚C)
±20%, ±10% (at 120Hz)
10 seconds reflow at 260˚C, 10 seconds immersion at 260˚C
Capacitance Change •••••• Refer to * 1
Dissipation Factor •••••••••• Initial specified value or less
Leakage Current ••••••••••••Initial specified value or less
At--55˚C/ +125˚C, 30 minutes each, For 5 cycles,
Capacitance Change •••••• Refer to * 1
Dissipation Factor •••••••••• Initial specified value or less
Leakage Currentv •••••••••• Initial specified value or less
R230
45 45
20
1
mm
Type numbering system (Example : 10V 100µF)
Drawing
Dimensions
Dimensions
Standard Ratings
L
W
H
D
B
A
L
W
B
A
H
D
Solder electrode
(mm)
D dimension only for reference
F75
F72
∗As for the surge voltage, refer to page 332 for details.
F75
033
047
068
100
150
220
330
470
680
1000
1500
336
476
686
107
157
227
337
477
687
108
158
R
R
R
R
R
R
R
R
R
M
M
R
R
R
R
R
(R)
M
M
M
R
R
R
4 6.3 10 16
0G 0J 1A 1C
V
F72 Code 068
100
150
220
330
470
680
1000
1500
2200
686
107
157
227
337
477
687
108
158
228
C
C •D
D
D •R
R
R
C
C •D
U •D
(U) •D •R
(U) •R
C
C •D
D
U •R
C
C
D
R
4 6.3 10 16
0G 0J 1A 1C
V
Code
Case code
LWHAB(D)
C7.1 ± 0.3 3.2 ± 0.3 2.5 ± 0.3 1.3 ± 0.3 3.6 ± 0.6 (6.0)
U7.1 ± 0.3 3.2 ± 0.3 2.0MAX. 1.3 ± 0.3 3.6 ± 0.6 (6.0)
D7.3 ± 0.3 4.3 ± 0.3 2.8 ± 0.3 1.3 ± 0.4 3.9 ± 0.6 (6.4)
R7.2 ± 0.3 6.0 ± 0.3 3.5 ± 0.3 1.3 ± 0.4 3.8 ± 0.6 (6.2)
(mm)
D dimension only for reference
Cap.(
µ
F) Cap. (
µ
F)
Case code
LWHAB(D)
R
7.2
±
0.3 6.0
±
0.3 1.2
±
0.3 1.3
±
0.4 3.8
±
0.6
(6.2)
M
7.2
±
0.3 6.0
±
0.3 2.0MAX. 1.3
±
0.4 3.8
±
0.6
(6.2)
Taping code(Refer to page 333 for details)
F
17
22
31
4A
51
60
77
8 121314
M
9RAQ2
10 11
Case code
Single face electrode
Capacitance tolerance
Rated capacitance Rated voltage
Series
Taping code(Refer to page 333 for details)
F
17
25
31
4C
51
65
77
8M
9D
10 11
Case code
Capacitance tolerance
Rated capacitance Rated voltage
Series
12 13 14
AQ2
Single face electrode
Compliant to the RoHS directive (2002/95/EC). F75
Maximum CV
Conformal
coated Chip
( )
The series in parentheses
are being developed. Please
contact to your local Nichicon
sales office when these
series are being designed in
your application.
Applications
Wireless modem e-book
Tablet PC SSD Smart meter
CAT.8100B
100 R F720G107MRC 4.0 8 0.70 ∗
150 R F720G157MRC 6.0 10 0.70 ∗
220 R F720G227MRC 8.8 12 0.70 ∗
330 R F720G337MRC 13.2 12 0.70 ∗
68 R F720J686MRC 4.3 6 0.75 ∗
100 R F720J107MRC 6.3 8 0.70 ∗
150 R F720J157MRC 9.5 10 0.70 ∗
220 R F720J227MRC 13.9 12 0.70 ∗
330 R F720J337MRC 20.8 12 0.70 ∗
1000 M F720J108MMC 63.0 30 0.14 ±15
1500 M F720J158MMC 95.0 45 0.14 ±20
47 R F721A476MRC 4.7 6 0.80 ∗
68 R F721A686MRC 6.8 6 0.75 ∗
100 R F721A107MRC 10.0 8 0.70 ∗
150 R F721A157MRC 15.0 10 0.70 ∗
220 R F721A227MRC 22.0 12 0.70 ∗
470 M F721A477MMC 47.0 30 0.14 ±15
680 M F721A687MMC 68.0 35 0.14 ±20
1000 M F721A108MMC 200 45 0.14 ±20
33 R F721C336MRC 5.3 6 0.90 ∗
47 R F721C476MRC 7.5 6 0.80 ∗
68 R F721C686MRC 10.9 6 0.75 ∗
4V
6.3V
10V
16V
*1
∆C/C
(%)
Part Number
Disspation
Factor
(
%@120Hz
)
Leakage Current
(
µ
A)
Case
code ESR
(
Ω
@100kHz)
Rated Volt
Rated
Capacitance
(
µ
F)
330 C F750G337MCC 13.2 10 0.15 ∗
470 C F750G477MCC 18.8 14 0.12 ∗
470 D F750G477MDC 18.8 14 0.12 ∗
680 D F750G687MDC 27.2 18 0.12 ∗
1000 D F750G108MDC 40.0 24 0.12 ∗
1000 R F750G108MRC 40.0 24 0.12 ∗
1500 R F750G158MRC 60.0 30 0.12 ∗
2200 R F750G228MRC 88.0 45 0.07 ∗
220 C F750J227MCC 13.9 10 0.20 ∗
330 C F750J337MCC 20.8 10 0.15 ∗
330 D F750J337MDC 20.8 10 0.15 ∗
470 U F750J477MUC 29.6 15 0.10 ∗
470 D F750J477MDC 29.6 14 0.12 ∗
680 D F750J687MDC 42.8 18 0.12 ∗
680 R F750J687MRC 42.8 18 0.12 ∗
1000 R F750J108MRC 63.0 24 0.12 ∗
150 C F751A157MCC 15.0 10 0.22 ∗
220 C F751A227MCC 22.0 10 0.20 ∗
220 D F751A227MDC 22.0 10 0.20 ∗
330 D F751A337MDC 33.0 10 0.15 ∗
470 U F751A477MUC 94.0 30 0.15 ±20
470 R F751A477MRC 47.0 14 0.12 ∗
68 C F751C686MCC 10.9 10 0.22 ∗
100 C F751C107MCC 16.0 10 0.22 ∗
150 D F751C157MDC 24.0 10 0.22 ∗
220 R F751C227MRC 35.2 10 0.20 ∗
4V
6.3V
10V
16V
*1
∆C/C
(%)
Part Number
Disspation
Factor
(
%@120Hz
)
Leakage Current
(
µ
A)
Case
code ESR
(
Ω
@100kHz)
Rated Volt
Rated
Capacitance
(
µ
F)
SOLID TANTALUM ELECTROLYTIC CAPACITORS
F72
F75
Standard Ratings
Standard Ratings
*1 : ∆C/C Marked "∗"
F75 ALL Case (%)
Damp Heat ±10
Tempereature cycles ±5
Resistance soldering heat
±5
Surge ±5
Endurance ±10
*1 : ∆C/C Marked "∗"
F72 ALL Case (%)
Damp Heat ±10
Tempereature cycles ±5
Resistance soldering heat
±5
Surge ±5
Endurance ±10
CAT.8100B
Compliant to the RoHS directive (2002/95/EC).
F98 Specifications
Type numbering system (Example : 6.3V 10µF)
Drawing
LW1S2
W2HS1
M1.6 0.85 0.65 ± 0.1 0.8 ± 0.1 0.5 ± 0.1
0.6
±
0.1
U
1.10 ± 0.05 0.60 ± 0.05 0.35 ± 0.05 0.55 ± 0.05
0.3 ± 0.05
0.5
±
0.05
(
mm
)
Case Code
L
H
W1
W2
S1S2S1
S2.0 1.25 0.9 ± 0.1 0.8 ± 0.1 0.5 ± 0.1
1.0
±
0.1
+0.2
-0.1
+0.2
-0.1
+0.2
-0.1
+0.2
-0.1
Rated voltage
(Voltage code)
J
U Case M Case
Rated voltage
(Voltage code)
Capacitance code
Js
S Case
Taping code
(Refer to page 333 for details)
F
19
28
30
4J
51
60
76
8M
9M
10 11
Case code
Capacitance tolerance
Rated capacitance Rated voltage
Series
Marking
Standard Ratings
Category
Temperature Range
Capacitance Toler ance
Leakage Current
Dissipation Factor
Damp Heat
(Steady State)
Temperature Cycles
Resistance to Soldering
Heat
Surge∗
Endurance∗
Shear Test
Performance Characteristics
±20% (at 120Hz)
Refer to the table below
At 40°C, 90 to 95% R.H., For 500hours (No voltage applied)
Capacitance Change Refer to the table below (* 1)
Dissipation Factor 150%
or less of initial specified value
Leakage Current 200%
or less of initial specified value
Refer to the table below
Provided that
After 5 minute's application of rated voltage, leakage current at 85°C,
10 times or less than 20°C specified value.
After 5 minute's application of rated voltage, leakage current at 125°C,
12.5 times or less than 20°C specified value.
At --55°C / +125°C, For 30 minutes each, 5 cycles
Capacitance Change Refer to the table below (* 1)
Dissipation Factor
150% or less than the initial specified value
Leakage Current Initial specified value or less
10 seconds reflow at 260°C, 5 seconds immersion at 260°C
Capacitance Change Refer to the table below (* 1)
Leakage Current Initial specified value or less
Leakage Current Initial specified value or less
After application of surge in series with a 1kΩ resistor at the
rate of 30 seconds ON, 30 seconds OFF, for 1000 successive
test cycles at 85°C, capacitors shall meet the characteristic
requirements listed below.
Capacitance Change
Refer to the table below (* 1)
Dissipation Factor
150% or less than the initial specified value
Leakage Current
200% or less than the initial specified value
After 1000 hours' application of rated voltage in series with a
3Ω resistor at 85°C, capacitors shall meet the characteristic
requirements table below
Capacitance Change
Refer to the table below (* 1)
Dissipation Factor
150% or less than the initial specified value
Leakage Current
200% or less than the initial specified value
After applying the pressure load of 5N
for 10±1 seconds horizontally to the
center of capacitor side body which has
no electrode and has been soldered
beforehand on a substrate, there shall be
found neither exfoliation
nor its sign at the terminal electrode.
Keeping a capacitor surface-mounted on a substrate upside
down and supporting the substrate at both of the opposite
bottom points 45mm apart from the center of capacitor, the
pressure strength is applied with
a specified jig at the center of the
substrate so that substrate
may bend by 1mm as illustrated.
Then, there shall be found no
remarkable abnormality on the
capacitor terminals.
Item
--55 to +125°C (Rated temperature : +85°C)
ESR Refer to the table below
Terminal Strength
5N (0.51kg • f)
For 10 ± 1 seconds
20
R230
45 45
1
mm
Resin-molded Chip,
High Capacitance Series
∗As for the surge voltage, refer to page 332 for details.
SOLID TANTALUM ELECTROLYTIC CAPACITORS
( )
The series in parentheses are being developed.
Please contact to your local Nichicon sales office when
these series are being designed in your application.
M
1
2.2
4.7
10
22
33
47
68
100
220
105
225
475
106
226
336
476
686
107
227
U
U
M
M
M
M•S
M•S
S
U•M
(U) •M
M
M
M• S
S
U•M
(U) •M
M
(M) • S
(M) • S
S
M
M
M
S
4 6.3 10 16 20 25
0G 0J 1A 1C 1D 1E
V
Cap.(µF)
Code M---
---
---
a
J
n
s
w
A
J
±30
±30
±30
±30
±30
±30
±30
±30
±30
±30
±30
±30
±30
±30
±30
±30
±30
±30
±30
±30
±30
±30
±20
±30
±30
±30
±30
±30
±20
±30
±30
4.7
10
22
33
47
68
68
100
100
220
4.7
4.7
10
22
33
47
47
100
2.2
2.2
4.7
10
22
33
47
1
2.2
4.7
10
1
1
4V
6.3V
10V
16V
20V
25V
*1
∆C/C
(%)
Part Number *2Leakage
Current
(µA)
Disspation
Factor
(%@120Hz)
Case
code ESR
(Ω@100kHz)
Rated Volt Rated
Capacitance
(µF)
Capacitance
code
*2 : Leakage Current
After 5 minute's application of rated voltage, leakage current at 20
˚C.
Applications
Smartphone Wireless module
Mobile phone Hearing aid
We can consider the type of compliance to AEC-Q200.
Please contact to your local Nichicon sales office
when these series are being designed in your application.
U
U
M
M
M
M
S
M
S
S
U
M
M
M
M
M
S
S
U
M
M
M
S
S
S
M
M
M
S
M
M
F980G475MUA
F980G106MUA
F980G226MMA
F980G336MMA
F980G476MMA
F980G686MMA
F980G686MSA
F980G107MMA
F980G107MSA
F980G227MSA
F980J475MUA
F980J475MMA
F980J106MMA
F980J226MMA
F980J336MMA
F980J476MMA
F980J476MSA
F980J107MSA
F981A225MUA
F981A225MMA
F981A475MMA
F981A106MMA
F981A226MSA
F981A336MSA
F981A476MSA
F981C105MMA
F981C225MMA
F981C475MMA
F981C106MSA
F981D105MMA
F981E105MMA
0.5
0.8
0.9
1.3
1.9
27.2
2.7
80.0
4.0
132
0.6
0.5
0.6
1.4
4.2
29.6
3.0
63.0
0.5
0.5
0.5
1.0
2.2
3.3
9.4
0.5
0.5
0.8
1.6
0.5
0.5
20
25
15
30
40
50
30
60
35
80
20
20
8
20
35
45
25
50
15
6
6
20
20
30
35
6
6
12
18
6
8
20
20
7.5
4
8
10
4
10
4
5
20
7.5
6
6
8
10
6
8
15
7.5
6
7.5
4
6
5
10
10
12
4
10
10
CAT.8100B
